First and Second Law Evaluation of Multipass Flat-Plate Solar Air Collector and Optimization Using Preference Selection Index Method

Luan, Nguyen Thanh; Phu, Nguyen Minh

doi:https://doi.org/10.1155/2021/5563882

Mathematical Problems in Engineering

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Abstract Introduction Model Formulation Results and Discussion Conclusions Appendix Data Availability Conflicts of Interest Acknowledgments References Copyright Related Articles

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Optimal Design, Control, and Identification of Energy Conversion Systems

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Research Article | Open Access

Volume 2021 | Article ID 5563882 | https://doi.org/10.1155/2021/5563882

First and Second Law Evaluation of Multipass Flat-Plate Solar Air Collector and Optimization Using Preference Selection Index Method

Nguyen Thanh Luan¹and Nguyen Minh Phu²

Academic Editor: Francisco Beltran-Carbajal

Received10 Jan 2021

Revised28 Feb 2021

Accepted18 Mar 2021

Published28 Mar 2021

Abstract

In this paper, different flow configurations of multipass flat-plate air collectors are explored. Multiple passes are formed from glass cover, absorber plate, and back plate. Five types of air collectors were analysed and optimized with respect to maximum efficiencies and minimum cost. The analytical prediction of the heat exchanger, pressure loss, and efficiencies was presented. The effects of mass flow rate from 0.01 to 0.02 kg/s, air channel depth from 15 to 30 mm, and collector length from 1.5 to 2.5 m on different configurations were examined and compared. The results of the parametric study show that the triple-pass type has the greatest efficiency, whereas the smallest efficiency is of the single-pass type. Among double-pass types, the type with two glass covers and natural convection heat transfer achieved the highest effective and exergy efficiencies due to a reduction in the top loss. Double-pass type with single glass cover is not recommended from both energy and exergy standpoints. As the collector length increases, the effective efficiency decreases, but the exergy efficiency increases. The exergy performance of the triple-pass type can reach up to 5% at the air flow rate of 0.005 kg/s. Finally, multiobjective optimization using the preference selection index method is conducted with three targets including effective efficiency, exergy efficiency, and number of plates. Optimal results show that the triple-pass type with the lowest air flow rate and the longest length is the best. The effective and exergy efficiencies for the best case were found to be about 52.1% and 4.7%, respectively. However, this type with the highest flow rate and the shortest length is the worst.

1. Introduction

The national sustainable energy strategy always gives priority for developing renewable energy. Tropical countries like Vietnam promote solar energy conversion due to vast and stable radiation intensity during the year. The common types of solar thermal energy conversion are solar power, solar hot water, and solar hot air. The first two kinds have been developing stably and commercially for a long time, while the solar hot air has been researching. This continuous research is due to two major problems. Firstly, the thermal energy of hot air cannot be stored like hot water because the air specific heat and density are small compared to water. Secondly, the small thermal conductivity of the air results in a low convection heat transfer coefficient. However, the application of solar air heater (SAH) is widespread for space heating [1], regeneration of desiccant [2], and drying of agricultural products [3]. Facing the needs and limitations of SAH, research on improving SAH performance is always paid attention [4]. Heat transfer improvement between the absorber plate and the air in the collector can be mentioned as the insertion of vortex generators [5], inclined plates [6], or roughness ribs on the absorber surface [7] to diminish the viscous sublayer close to the surface and create mixing of the primary and secondary flows.

Another measure is the collector duct divided into multiple air passes to reduce heat loss at the top of SAH because of the high temperature of the absorber plate. Previously, Chandra et al. [8] established an analytical model and equivalent resistance method to calculate triple-pass air collector. Predictions from the two approaches were compared with experimental data to indicate discrepancies. Choudhury et al. [9] theoretically solved triple-pass air collector with single and double glass covers. They reported that low air flow rate and short collector length were the cost-effective solutions. Forson et al. [10] studied the theory and indoor experiment of double-duct SAH in the natural convection mode of air. They concluded that the collector efficiency decreased with increasing collector area. Ramadan et al. [11] have inserted a packed bed in the first pass of a double-pass SAH to increase the heat transfer surface. They recommend an air flow rate of less than 0.05 kg/s to achieve high efficiency. Sopian et al. [12] added porous media to the second pass of a double-pass SAH. This correction achieves collector efficiency up to 70% which is greater than the traditional single-pass SAH. Ramani et al. [13] expanded the study of double-pass SAH with the porous material configuration at the second pass. They claim that the collector efficiency is 25% higher than that of the double-pass SAH without porous and 35% higher than that of the single-pass SAH. Correction of the absorber surface to enhance heat transfer has been a concern for the past decade. El-Sebaii et al. [14] used a v-corrugated absorber surface in a double-duct SAH. They realized that the air temperature leaving the collector was 5% higher and the efficiency was 14% higher than the smooth absorber surface. A finned absorber plate in a double-pass SAH was proposed and examined by El-Sebaii et al. [15]. They reported that the optimum air flow rate was 0.0125 kg/s to achieve the maximum hydraulic thermal efficiency of 40%. Ho et al. [16] studied the effect of air recirculation fraction to the second pass in a wire mesh SAH. They reported that the optimal fraction was 0.5 for flat-plate collectors and 1 for wire mesh packed collectors. Yeh [17] studied to divide the airflow between the absorber plate and the back plate into multiple passes. The results showed that when the number of passes increased, the thermal efficiency increased, but the pressure loss penalty was not significant.

Recently, besides evaluating the energy efficiency and cost of multipass air collectors, the exergy efficiency estimation of the collector has been noted to fulfill the requirements needed for a thermal device. The exergy analysis is to quantify the availability of solar radiation which can be converted into its work potential and irreversibility due to exergy destruction. Velmurugan and Kalaivanan [18–21] studied the energy and exergy of multipass collectors with different configurations including ribbed, finned, wire mesh absorber plates. They reported that a mixed type of wire mesh in the second pass and fin in the first pass provides the highest energy and exergy efficiencies. Raj et al. [22] evaluated the exergy performance of a SAH under outdoor conditions. They concluded that the exergy efficiency increased with day time and mass flow rate due to the higher extracted useful energy. Abo-Elfadl [23] proposed 4E (energy, exergy, economic, and environmental) model to comprehensively investigate a double-pass SAH. They pointed out that finned SAH is the most feasible one in terms of exergoeconomic point of view. Experimental studies on different modifications for multipass SAH have been performed to demonstrate their effectiveness [24–26]. In addition, with the development of numerical algorithms and computer processors, CFD (computational fluid dynamics) studies have been conducted to reduce the experimental time and costs [27–31]. More recently, Heydari et al. [32] proposed and numerically examined a novel helical airflow path around triangular channels. From the simulation results, the distributions of variables within the SAH such as velocity, pressure, and temperature are clarified to explain the mechanism of heat transfer enhancement and the potential for efficiency improvement. Multipass air collector applications for drying agricultural produce and integrating photovoltaic are also found in the literature [33–35].

Extensive review indicates that there is more variation in the multipass air collector to improve heat transfer such as wire mesh, porous, or fin. But in all, it is still based on a flat-plate collector with a certain number of passes. No previous works have been found to address the simultaneous comparison of multipass SAHs and multiobjective optimization to determine the most feasible collector. Therefore, this study focuses on evaluating the flat-plate collector with different number of glass covers, absorber plate, and back plate in order to examine all the possible passes of air. Energy, exergy, and optimization studies firmly confirm the pertinent type among the many configurations and major dimensions of air collectors through an analytical investigation coupled to an optimization method called multicriteria decision-making technique.

2. Model Formulation and Validation

Figure 1 shows the five types of flat-plate collectors that were investigated for energy, exergy, and optimization in this study. Type 1 consists of two glass covers, an absorber plate, and a back plate. The air travels from top to bottom via 3 passes. Type 2 consists of a glass cover, an absorber plate, and a back plate. Therefore, two passes can be created from these plates. Type 3 consists of two glass covers and one back plate where the air can travels through two passes. A four-plate configuration with two passes is seen in type 4, in which the air between the two glass covers is naturally convected. Type 5 consists of two glass covers and one absorber plate with the air blowing through single pass in order to compare with the multipass types of 1 to 4.

(a)

(b)

(c)

(d)

(e)

2.1. Thermohydraulic Modelling

The mathematical model is presented in this section with the following assumptions:(i)Flow is steady, incompressible, and one-dimensional (1D). In practical applications, such as convective drying, an air velocity was verified to obtain drying conditions. Thus, the airflow is assumed to be steady. The air velocity inside the solar air heater duct is moderate so that air temperature is high enough to serve a certain duty. Therefore, the airflow is considered incompressible. Variation of air pressure and temperature is along with duct length leading to the 1D flow consideration.(ii)Thermal conduction in glass cover, absorber plate, and back plate is not considered due to their small thicknesses. The temperatures of these plates are homogeneous and equal to the average temperature. Multipoint temperature measurement on a plate is required in experiments, and the average temperature can be estimated by taking arithmetic mean [26].(iii)The thermophysical properties of air, glass, and plates are constants because of low temperature change of a flat-plate air collector.

Equations (1)–(7) present the energy balance for type 1 as illustrated in Figure 2(a). Type 1 consists of 4 plates (2 glass covers, 1 absorber plate, and 1 back plate) and the fluid at 3 passes, so it takes seven equations to find seven corresponding temperatures. The thermal balance equation for the top glass cover is given below. The solar thermal energy absorption of the glass is equal to the amount of thermal energy released to the surrounding by convection and radiation, the heat transfer to the air in the first pass, and the heat transferred by radiation between the two glass covers [13]:

The air in the first pass receives heat from the two glass covers and increases its temperature. The temperature gradient can be approximated by the temperature difference between the inlet and outlet of the channel [16, 20]:

The lower glass cover absorbs solar radiation equaled to the convection heat transfer with the airflows at first and second passes, and the radiant heat exchanges with the upper glass cover and the absorber plate:

Thermal balance of fluid in the second pass is formed via convection heat transfer with the lower glass cover and absorber plate:

The heat gain from solar radiation of the absorber plate is balanced with the heat transferred to the fluid at the second and third passes and with the radiant heat transfer to the lower glass cover and back plate:

Thermal balance of fluid in the third pass is composed of convective heat transfer with absorber plate and back plate:

The back plate received thermal radiation from the absorber plate equilibrates with the convection heat exchange to the air in the third pass and the heat loss from the back plate to the environment:

In the above equations, the fluid temperature (T_f) in a pass is taken as the average value of inlet and outlet temperatures of the pass. This is due to the fact that the convective heat transfer coefficient (h_c) was developed based on the fluid bulk mean temperature.

Equations (1)–(7) are rearranged in matrix form as follows:where

The appendix presents the system of equations for determining the temperatures of the remaining types associated with the energy balance diagram in Figures 2(b)–2(e). From equation (9), it is possible to solve seven temperatures once the convection heat transfer coefficients and radiant heat transfer coefficients are specified. The convection heat transfer coefficient of the top glass cover with the ambient air is calculated from McAdams’ equation as follows [36]:

The forced convective heat transfer coefficient of the air in the collector is predicted using the Dittus–Boelter formula as follows [37]:

The natural convection heat transfer coefficient between 2 glass covers of types 4 and 5 is estimated by [20]

The radiant heat transfer coefficient from the top glass cover to the sky is evaluated by the following correlation:

The sky temperature is calculated from the following equation [38]:

Generally, the radiant heat transfer coefficient between the two surfaces s1 and s2 is computed from their temperature and emissivity as follows [39]:

The conductive heat transfer coefficient from the back plate to surroundings is determined by

The hydraulic diameter is defined as follows:

The Reynolds number is given by

The thermal efficiency, i.e., first law efficiency, is the ratio of the heat gain received by air through SAH to the solar radiation coming from the absorption surface:where Q is the useful heat gain received by the air: .

When reconfiguring a thermal device to improve its heat transfer, it is likely that pressure loss also increases. Therefore, it is necessary to evaluate hydraulic dissipated power. The pressure loss of the air through the collector is the sum of the pressure loss due to friction and the minor loss due to 180° return bend between successive passes:

The frictional pressure loss is evaluated aswhere f is the friction factor.

The friction factor can be calculated by [11]

Minor pressure loss by 180° return bend can be estimated aswhere K_bend is minor loss coefficient for 180° return bend, K_bend = 2.2 [19].

The energy required to transport fluid against pressure loss is calculated as follows:

The difference between the useful heat gain and pumping power is attributed to effective efficiency aswhere C_o is the conversion factor considering the thermal energy equivalent of blower power, C_o = 0.2 [38].

2.2. Exergy-Based Modelling

The input exergy of the SAH is constituted by the air inflow and solar radiation source as follows [5, 38]:where T_sun is the sun temperature, T_sun = 4350 K [38], and A_c = L_b is the absorber plate area.

The exergy losses of a solar air heater have been derived into five components including optical loss, the loss due to heat transfer from the absorber plate to the environment, the loss due to solar radiation absorption of the absorber plate, the loss due to heat transfer from the absorber plate to the air, and the frictional loss of the air flowing in SAH. These qualities are quantified as follows:(1)Optical exergy losses:(2)Exergy losses by convection and radiation heat transfer from the absorber plate to the environment: where U_L is the total loss coefficient: The heat loss from the top of each SAH is calculated by convection and radiation heat transfer coefficients above absorber plate as [38](3)Exergy losses by absorption of radiation by the absorber plate: where n_g is the number of glass covers.(4)Exergy losses by heat transfer to the working air: where T_f is the mean temperature of the working air, T_f = 0.5 (T_a + T_o).(5)Frictional exergy losses of the working air:

The first two kinds of exergy losses are external losses. The remaining kinds are known as internal losses. The total exergy losses are determined by summing the abovementioned exergy losses:

The exergy efficiency can be calculated by summing the total exergy losses and input exergy as follows:

2.3. Preference Selection Index Method for Multiobjective Optimization

Choosing a final solution may involve multiobjective optimization. In this study, three objective functions were selected including maximum effective efficiency, maximum exergy yield, and minimum total number of plates. The total number of plates is composed of glass covers, absorber plate, and back plate. This is a parameter related to the capital cost of a multiple pass air collector so it should be minimal. There are many multiobjective optimization methods. The preference selection index (PSI) method is chosen in the current work due to its explicit approach, simplicity, and no need to choose weights [40, 41]. The method is the objective approach oriented to multicriteria decision-making which was recently devised by Mania and Bhatt [42]. Nowadays, the PSI method is widely applied in many fields [43].

The performance procedure of the PSI method can be summarised as follows [40, 41]: Step 1: normalization of criteria For criteria needed to be maximized, i.e., η_eff and η_II: For criterion needed to be minimized, i.e., total number of glass cover, absorber plate, and back plate:(i)where i is i^th case, there are 135 cases in the current study, and therefore, i = 1 to 135. Step 2: find the mean value of an objective Step 3: compute the preference variation value Step 4: evaluate deviation of preference variation value Step 5: estimate the overall preference value Step 6: calculate the preference selection index value for each case

Table 1 displays the input parameters entered into the mathematical model for all of the collector types examined. The above system of mathematical equations is solved in the Engineering Equation Solver (F-chart software) which specializes in solving system of nonlinear equations. Figure 3 shows the comparison of the calculated results from the current study with the published experimental results for collector types 4 and 5. It can be stated that the results in this study are slightly overestimated compared to the experimental results. This is because the predictions are limited as the above assumptions compared with the practical applications. However, analytical predictions coincide well with the experimental approaches. Verifications have been performed about heat transfer and hydraulics of single-pass and multipass SAHs. Confirmation on the prediction of the exergy analysis model was presented in our previous study [5]. It is not repeated here for the sake of brevity. Hence, the mathematical modelling was extended to the remaining types and carried out further evaluation for all collectors.

(a)

(b)

3. Results and Discussion

This section presents the effects of air mass flow rate (m), channel height (H), and collector length (L) on the energy and exergy performance of the types under consideration. Figures 4 and 5 consider the effect of mass flow rate while the collector geometry parameters are fixed. It can be observed in Figure 4 that the effective efficiency increases with the mass flow rate. As the flow rate increases, the intensity of the heat exchange increases, thus enhancing the useful heat gain of the air received from glass cover and plates. However, the flow rate increases as a result of rising the pressure loss. But the pressure loss penalty is negligible due to air moving in the smooth channels. At high flow rates, the efficiency increases slightly because of remarkable pressure loss. It can be seen that type 1 (triple-pass SAH) has the highest performance and type 5 (single-pass SAH) has the lowest performance. This verifies that a multipass air collector reduces top loss and higher temperature rise of air because the air receives thermal energy from four plates (two glass covers, one absorber plate, and one back plate). The double-pass types have fairly close efficiencies in which type 4 reveals better performance because this type owns two glass covers in natural convection heat transfer, thus significantly reducing top loss. At a small flow rate, the triple-pass SAH (type 1) is nearly twice as efficient as the single-pass SAH (type 5). However, at a large flow rate, the effective efficiency of type 1 is only 20% higher than that of type 5 due to the long travel of the air inside the triple-pass SAH.

Figure 5 shows at low flow (less than 0.02 kg/s) the triple-pass collector earns the greatest exergy performance followed by double-pass and single-pass collectors. This is because the exergy loss decreases with the increase in the pass number. At low flow, a collector with a large pass number has a high exergy performance due to the higher temperature of the fluid and lower temperature of absorber plate reducing exergy losses. Among the double-pass types (types 2, 3, and 4), the single glass cover SAH (type 2) has the smallest exergy performance due to the highest exergy loss from the absorber plate to the environment. Exergy performance obtained the maximum value at a certain flow rate due to trade-off of increase in frictional exergy loss and a decrease in exergy loss by heat transfer from the absorber plate to the environment with mass flow rate. At high mass flow rates, the exergy performances of the double-pass SAHs seem to be identical. This means that the absorber plate temperature of the double-pass SAHs is almost the same leading to alike exergy losses at those flow rates.

Figures 6 and 7 show the energy and exergy performance of multipass SAH with collector length (L) at fixed air flow rate and channel height. It can be seen that the effective efficiency of air collectors decreases with increasing collector length. This is supposed due to the fact that the outlet air temperature does not increase linearly with the length. The fluid absorbs heat and increases its temperature along the flow path so that the longer length results in the lower temperature difference between the hot surface and the fluid. The small temperature difference causes an increase in useful heat gain by less than the order unity of the heat transfer length. At the same length, the effective efficiency increases with increasing the number of passes. For all double-pass types, type 4 is the best and type 2 is the worst as noted above. The triple-pass type has the largest slope because of the highest pressure loss. Contrary to the effective efficiency, the exergy efficiency increases with the collector length as can be seen in Figure 7. This is owing to the fact that the exergy loss due to heat transfer from the absorber plate to the fluid decreases because of the small temperature difference between the absorber plate and the airflow. Triple-pass SAH can achieve exergy performance of up to 5%. This is a very encouraging performance for a solar air heater. As it is known, SAH’s exergy efficiency is very low, say 2%, due to the great exergy destruction of converting solar radiation into heat [7].

The effect of channel depth (H) on effective and exergy efficiencies is shown in Figures 8 and 9 with fixed air flow rate and collector length. Increasing the channel depth reduces the velocity of air blowing through hot surfaces leading to low convection heat transfer coefficient. Also, the low air velocity increases the surface temperatures resulting in increased heat losses such as top loss and the loss from back plate to the environment. Increasing the temperature of the plates with the depth increases the exergy losses due to heat transfer to the fluid and heat loss. Hence, the exergy performance decreases with the increase in the air channel depth as shown in Figure 9. However, it is worth noting that the exergy efficiency of the triple-pass SAH (type 1) reaches an extreme at the depth of 19 mm. This can be explained by the fact that at a depth of less than 19 mm, the fluid passing in the 3 passes reduces the temperature of the plates and the smallest top loss compared to other types. Thus, the exergy performance of the triple-pass type increases with the air channel depth from 15 mm to 19 mm.

The analysis above showed the influence of the design, operation parameters, and collector type on the performance. The characteristics of each collector and the maximum efficiencies have been indicated. To initialize the optimization for searching the final solution, in this study, there are 5 types of collector and 3 design and operation parameters including mass flow rate (range m = 0.01 − 0.02 kg/s), collector length (L = 1.5 − 2.5 m), and air channel height (H = 20 − 30 mm) each at three levels. Hence, there are 135 cases in total which need to select the best one. Typically, Table 2 presents 27 cases for type 1 with inputs and outputs.

Table 3 shows the calculated values from steps 3–5 of the PSI method for the objective functions under consideration. Table 4 exhibits selective 10 cases including 5 best cases (the highest preference selection indices) and 5 worst cases (the smallest preference selection indices). It is confirmed that type 1 with lowest flow rate, maximum collector length, and moderate channel depth reaches the final optimal solution. This is also consistent with the statement in the above parametric study. Otherwise, type 1 with the largest airflow is the worst case. In addition, single-pass SAH (type 5) is also three of five worst cases (cases 120, 114, and 111). From the PSI method, it can be concluded that types 1 and 3 with suitable geometry and operating parameters are the two SAHs that should be selected in multipass air collector configurations.

Figure 10 shows a comparison of optimal results from the PSI method for the objective function of effective efficiency. Two configurations compared to the current study were single-pass SAHs with impinging air jet plate [41] and V down perforated baffles on absorber plate [40]. It can be seen that the effective efficiency of flat-plate air collector in the present study is lower than that of collectors with special modification and insertion. This results in low convection heat transfer coefficient of a smooth duct compared to others. However, with the change of flow configuration to types 1 (triple pass) or 3 (double pass), the flat-plate air collector can compete with other types. Especially at rank 5, the effective efficiency of triple-pass SAH is approximately equal to single-pass SAH with the roughness of V down perforated baffles.

4. Conclusions

The various configurations of the multipass flat-plate air collector have been analysed in this paper. The configurations include the number of passes from 1 to 3, and the number of glass covers is 1 or 2 with/without back plate. Independent parameters comprise collector length, air channel depth, and air mass flow rate to examine the efficiencies. Multiobjective optimization of the maximum effective, exergy efficiencies, and minimum number of plates, i.e., glass cover, absorber plate, and back plate, were conducted using the preference selection index method. The main results are drawn as follows:(i)Triple-pass SAH has the highest effective efficiency followed by double-pass type and single-pass type. The efficiency of the triple-pass type is 30% higher than that of single-pass type. Among the double-pass types, type 4 obtained the largest effective efficiency.(ii)Exergy performance is maximum when the air flow rate is between 0.005 and 0.01 kg/s.(iii)The triple-pass type has the highest exergy performance that is twice as high as the single-pass type. Type 4 also yielded the biggest effective efficiency among the double-pass SAHs.(iv)Effective efficiency decreases when increasing the collector length. In contrast, exergy performance increases with the length.(v)As the collector depth increases, the effective efficiency decreases. The exergy performance of the triple-pass type is maximum at the collector depth of 19 mm. For other types, the exergy performance decreases when increasing the collector depth. Adopting the multiobjective optimization, it is obviously confirmed that the triple-pass solar air heater is the best arrangement at low flow rate and the worst case at high flow rate. This is because at low flow rate, the effective efficiency and exergy efficiency of triple-pass type are quite large compared to other types. But at high flow rate, the exergy performance is too poor with a considerable investment cost.

Appendix

A. Thermal Transport Modelling for Solar Air Heater Types 2 to 5

A.1. Type 2

Glass cover

Air in 1^st pass

Absorber plate

Air in 2^nd pass

Back plate

A.2. Type 3

Upper glass cover

Air in 1^st pass

Lower glass cover

Air in 2^nd pass

A.3. Type 4

Upper glass cover

Lower glass cover

Air in 1^st pass

Absorber plate

Air in 2^nd pass

Back plate

A.4. Type 5

Upper glass cover

Lower glass cover

Air

Absorber plate

Nomenclature

A_c:	Area of the absorber plate (m²)
b:	Collector width (m)
c_p:	Specific heat at a constant pressure (J/kg-K)
D_h:	Hydraulic diameter (m)
EX:	Exergy (W)
f:	Friction factor
h:	Heat transfer coefficient (W/m²-K)
H:	Channel depth (m)
I:	Solar radiation (W/m²)
k:	Thermal conductivity (W/m-K)
L:	Collector length (m)
m:	Air mass flow rate (kg/s)
n_glass:	Number of glasses
n_pass:	Number of passes
N_plate:	Total number of plates (absorber plate, back plate, glass cover)
:	Pressure (Pa)
Pr:	Prandtl number
Q:	Heat transfer rate (W)
Re:	Reynolds number
T:	Temperature (K)
t:	Thickness (m)
U_L:	Overall heat loss coefficient (W/m²-K)
U_t:	Top loss coefficient (W/m²-K)
V:	Velocity (m/s)

Greek symbols

α:	Absorptivity
ρ:	Air density (kg/m³)
Δ:	Difference
μ:	Dynamic viscosity (Pa.s)
η:	Efficiency
ε:	Emissivity
Ω:	Preference selection index
σ:	Stefan constant
τ:	Transmissivity

Subscripts

a:	Ambient
b:	Back plate
c:	Convection
Eff:	Effective
f:	Fluid (air)
:	Glass cover
I:	First law
i:	Insulation
II:	Second law
o:	Outlet
:	Absorber plate
r:	Radiation
s:	Sky
:	Wind.

Data Availability

No data were used to support this study.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Acknowledgments

This research is funded by the Vietnam National University Ho Chi Minh City (VNU-HCM) under grant number B2021-20-06.

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Copyright © 2021 Nguyen Thanh Luan and Nguyen Minh Phu. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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