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Article

The Effect of the Angle of Inclination on the Efficiency in a Medium-Temperature Flat Plate Solar Collector

National Center of Research and Develop of Technology-TecNM-SEP, Interior Internado Palmira s/n, Cuernavaca 62490, Morelos, Mexico
*
Author to whom correspondence should be addressed.
Energies 2017, 10(1), 71; https://doi.org/10.3390/en10010071
Submission received: 20 August 2016 / Revised: 8 November 2016 / Accepted: 15 December 2016 / Published: 9 January 2017

Abstract

:
In this experimental work, the effects of the inclination angle β and the (TiTa)/G on the efficiency and the UL-value were investigated on a medium-temperature flat plate solar collector. The experiments were based on steady-state energy balance, by heat flow calorimetry at indoor conditions and considering the standard American National Standard Institute/American Society of Heating Refrigerating and Air Conditioning Engineers (ANSI/ASHRAE) 93-2010. The solar radiation was emulated by the Joule effect using a proportional integral derivative (PID) control considering two conditions of the absorber temperature, Case 1: (ToTi) > 0, and Case 2: (ToTi) = 0. The inclination angles were 0°–90° and the (TiTa)/G were 0.044–0.083 m2·°C/W and 0.124–0.235 for Case 1 and Case 2, respectively. The variations of β and (TiTa)/G cause efficiency changes up to 0.37–0.45 (21.6%) and 0.31–0.45 (45.0%), respectively, for Case 1. Also, the UL(β) reached changes up to 10.1–12.0 W/m2·°C (19.2%) and 8.4–12.0 W/m2·°C (41.7%), respectively, for Case 1. The most significant changes of UL(β)/UL(90°) vs. β were 8.0% at the horizontal position for Case 1, while for Case 2, the maximum change was 1.8% only. Therefore, the changes of the inclination angle cause significant variations of the convective flow patterns within the collector, which leads to considerable variation of the collector efficiency and its UL value.

1. Introduction

The solar heating systems for industrial applications have a great potential to reduce the demand for conventional energy. This technology could supply 406 GWth [1]. Currently, the world’s solar heating by flat plate collectors is about 83.9 GWth [1]. The glazing flat plate solar collectors are one of the most used devices for solar heating, due to being able to reach more than the desired temperatures, collecting direct and diffuse radiation at a lower cost due to their construction and operation simplicity [2]. The characterization and simulation have improved the commercialization and their applications in most heating processes. Therefore, anything focusing on better characterization of solar collectors has been welcomed for the solar heating industry because that allows reducing estimation uncertainty, in order to have a more accurate picture of their performance.
Most of the previous reports show theoretical and experimental models to determine the thermal efficiency of solar collectors, in terms of the transmittance-absorbance factor τα, the overall heat transfer UL and the heat removal factor FR [3]. These models usually consider the collector tilt angle with respect to the normal axis of the surface, mainly taking into account the variations with respect to the east-west axis, as a common daily variation. The ANSI/ASHRAE 93-2010 [4] and International Standard Organization (ISO) 9806:2013 [5] show methods to determine the influence of the incidence angle which only amend the first coefficient of the efficiency curve (FRτα). Then the tilt angle with respect to the North-South (N-S) horizontal axis is currently taken into account to determine a constant value of UL, as this varies only during the few days of the collector’s test [4,5]. Currently, the effect of the change of the inclination angle is included in the third coefficient of the collector efficiency curve along with many other effects, as well as in the Incident Angle Modifier (IAM) to fit the first coefficient [4].
Among the research models, previous works have also proposed an overall heat loss coefficient and experimental generalized correlations as complements to determine the solar collector’s efficiency [6,7,8,9]. However, these proposed models generally use a fixed inclination with respect to the N-S horizontal axis, according to the latitude of the evaluation place [10,11], thereby disregarding the fact that the second and third coefficients of the efficiency curve are functions of the UL. This latter is, in turn, dependent on the collector’s inclination, due to the changes of the convective flow pattern of the confined fluid between the absorber and the cover of the collector. To date, the determinations of UL as a function of the collector inclination β have been weakly studied, separating the effect of the confined fluid and the incidence solar radiation, as well as the effect of working at higher differences of temperature (TpTa), as is the case for medium-temperature solar collectors for industrial processes.
Ozoe et al. [12,13] and Alvarado et al. [14], among others, have shown the changes of the flow pattern with the collector inclination with respect to the horizontal position. However, lower (TpTa) and the collector’s inclination as used at characterization place do not make a big difference. Bava and Furbo [15] carried out a parametric experimental study varying the collector type, the solar collector fluid, the volume flow rate and the collector inclination to determine the performance in terms of efficiency. They found that the flat plate collector is most commonly used at inclination angles of 30°, 45° and 60° of, in a range of 20–100 °C. On the other hand, Sabatelli et al. [16] developed a test method to evaluate the efficiency uncertainty for the ISO 9806/1 standard. Beikircher et al. [17] developed a procedure to determine the collector thermal efficiency based on heat loss measurements without insulation. Bava and Furbo [15] found that the most important parameter in the sensibility of the UL is the inclination angle, which can represent 5%–8% of UL change. Thus, the use of a higher temperature between the absorber plate and the glazing cover, as well as the increase of the movement of products around the world, causes the effect of inclination on the collector’s efficiency, and more careful studies are required.
Therefore, a study of the effects of the inclination angle on the efficiency and the overall heat transfer coefficient was proposed and investigated in a glazing flat plate collector under inclinations from horizontal to vertical, varying (TiTa)/G for working conditions of some of the medium-temperature solar collectors.

2. Materials and Methods

2.1. Sampling

Figure 1 and Figure 2 show a sketch and a picture of the flat plate solar collector respectively. The sample is 2.00 m2 (1.00 m × 2.00 m) of gross collector area, with an aspect ratio of 40. The solar collector has a couple header tubes and five raising finned tubes, all of them of cooper, joined by tin-lead solder. The working fluid was water-glycol 10%–90%, considering variable heat capacity as function of the temperature [18]. The surface of absorber plate was covered with black matte paint with absorptance of 0.94. The solar transmittance of the glazing was 0.86. The spectral absorptance and transmittance were obtained according to CIE 130-1998 [19], using a spectrophotometer Shimadzu UV-3100, (Shimadzu Corpotation, Nakagyo-ku, Kyoto, Japan), in the range of 300–2500 nm, every 2.0 nm with ±0.1% of photometric uncertainty and 1.0% of wavelength uncertainty. The absorptance was obtained by normalizing the measured spectral absorptance according ISO 9050-2003 [20]. Table 1 shows the solar collector construction characteristics.

2.2. Experimental Design

The experimental design allows determining the UL and collector efficiency η, under inclinations from horizontal to vertical, at a range of (TiTa)/G. All of the rest variables involved in the experiment were considered without significant variations. Once the experiment works emulating the solar heating, part of the supplied energy heats the working fluid Qu, and the rest is transferred to the ambient as heat losses Ql(β), both of them also dependent from the β and (TiTa)/G. The UL(β,(TiTa)/G) and η(β,(TiTa)/G) are determined by flow calorimetry, based on steady-state energy balance according Figure 1, at indoor controlled conditions. Constant solar heating at (ToTi) > 0 and isothermal absorber plate at (ToTi) = 0 are considered in the study for comparison, looking for achieve suitable experimental uncertainty.
The incoming heat flux is GA, which is fixed and is not considered function of β. The outlet heat is the sum of the Qu(β) plus the heat loss flux Ql(β). The following considerations are taken in to account in the experiment: (a) steady state; (b) constant surrounding temperature and emissivity; (c) constant radiative exchange; (d) linear variation of Cp with the temperature; and (e) the mean plate temperature, Tp(β) is considered as the average temperature between outlet and inlet temperature (To(β) − Ti)/2.
Throughout each test once the absorber plate works, it heats the working fluid that flows through the raising tubes. Part of supplied energy heats the working fluid and the rest is transferred to the ambient as heat losses, both of them dependent from the β and (TiTa)/G. At indoor conditions, the solar heating is emulated by Joule effect and proportional integral derivative (PID) control, using electrical heater, making possible to replace (TiTa)/G by (TiTa)/(VI/Aτα), to achieve better experimental uncertainty, thus the solar heating is given by Equation (1).
G A = V I τ α
where τ and α are the glazing solar transmittance and the solar absorptance of the absorber respectively, and V and I are the electrical voltage and current respectively. Considering the above, due to the convective flow pattern varies with the tilt angle then the overall heat transfer coefficient in terms of β is calculated by:
U L ( β ) = V I Q u ( β ) A [ T p ( β ) T a ]
where the useful energy is Q u ( β ) = t 1 t 2 m ˙ C p ( T o ( β ) T i ) d t and the Q l ( β ) = A U L ( β ) [ T p ( β ) T a ] . And then, the collector efficiency, according ANSI/ASHRAE 93-2010, is given by:
η ( β ) = Q u ( β ) ( V I A τ α )

2.3. Experimental Setup

The heating of the absorber is homogenously distributed by means of the electrical heater and remains almost constant over each test. The experimental setup is sketched in Figure 2.
According the heating of the absorber two cases were considered. The Case 1 ((ToTi) > 0, Qu(β) ≥ 0): with considerable profile temperature in the raising tubes, also called non-isothermal absorber plate, which allows to achieve the UL and the collector efficiency. The Case 2 ((ToTi) = 0), Qu(β) = 0): also called isothermal absorber plate, which allows to achieve the UL only. In the Case 1, the GA is set to a specified value, therefore (ToTi) and (TpTa) are the output variables. In the Case 2, the (ToTi) are controlled close to zero by adjusting the VI, thus (TpTa) is the output variables only.
As is shown in Figure 2, the experimental set up allows mounting the sample with variable angle β at 0°, 30°, 45°, 60° and 90°, with uncertainty of ±0.1°. The (TiTa)/G are fixed at series of specified steps, by adjusting Ti and VI in the range of part of low and medium temperature solar collectors (0.044–0.084). The electrical heater supplied up to a maximum of 2000 W, with an uncertainty of ±5 W.
The temperature differentials (ToTi) and (TiTa) were measured using a type T thermocouple, 32 gauge wires, with an uncertainty of ±0.1 °C. A thermal bath supplied 10%–90% water-glycol mixture as working fluid, with an uncertainty of ±0.01 °C. The mass flow rate was 0.016 kg/s [15,21]; it was monitored with a turbine-flowmeter, with an uncertainty of 3%, and was also verified by weighing the water-glycol mixture, at specified time steps during the experimental campaign.
The experimental indoor condition allows to keep uniform surrounding temperature, surrounding emissivity, as well as to run the experiments with non-considerable changes of solar heating, ambient temperature, surrounding temperature and wind velocity. The 10%–90% water-glycol mixture allows minimizing adverse boiling effects.
A programmable Field Programmable Gate Array, NI-CompactRIO, 9022 (National Instruments, Austin, TX, USA), 32 bits data acquisition and Lab-VIEW software 2012 (National Instruments, Austin, TX, USA) were used to monitor, recorded and calculate the experimental variables at time steps of one second. During experiments, the steady state was verified by monitoring experimental data without considerable changes at each 30 min. Each data point corresponds to an average of over 1800 measurements, taken during a 30 min period. The test was made by triplicate for comparison.

3. Effect of the Parameters

The experiment focused on the behavior of the overall heat transfer and its effect on the collector’s efficiency as a function of the inclination angle and (TiTa)/G, emphasizing that Gf(β) and minimizing the effect of the changes of the rest of the variables. Three sets of 20 experiments were carried out for this purpose. The UL was studied at β (0°, 30°, 45°, 60° and 90°) and (TiTa)/G at (0.044, 0.056, 0.070, 0.083, 0.124, 0.140, 0.160, 0.195 and 0.235). The efficiency was the same for range β and at (TiTa)/G of (0.044, 0.056, 0.069, 0.083). Case 1 allows the study of the UL and efficiency at (ToTi) > 0, (Qu(β) > 0); the (TiTa)/G and Tp were 0.044, 66.8:0.056, 76.1:0.69, 85.3:0.82, 94.4, respectively. Case 2 allows the study of the UL only at (ToTi) = 0, (Qu(β) = 0); the (TiTa)/G and Tp were 0.235, 60:0.195, 70.0:0.160, 80:0.140, 90:0.124, 100, respectively. Table 2 shows the experimental conditions for the two cases.

3.1. UL vs. β and (Ti − Ta)/G

3.1.1. Case 1: (ToTi) > 0, (Qu(β) > 0)

Figure 3 shows UL vs. β and (TiTa)/G with its corresponding average of Tp. The experimental uncertainty of UL was ±0.25 W/m2·°C [22]. The Ti was increased to increase the value of Tp and then (TiTa)/G increased as well. It can be observed that the Qu decreased slower than the increase of (TpTa), causing a UL value reduction with the increase of Tp. As expected, according Equation (3), the results show that the energy loss (VIQu) increases as (TpTa) increases, while Qu slowly decreases and VI remains constant. Thus, the UL decrease due to the Qu decrease is slower than the increase of (TpTa), causing the UL value reduction with the increase of Tp.
As seen, UL(β) can achieve a reduction up to 12–10.1 W/m2·°C (19.2%), increasing the inclination angle from 0° to 90° at a constant (TiTa)/G of 0.44. At a constant β, the decreasing rate of the UL was accentuated at lower values of (TiTa)/G. The UL can change up to 12.0–8.4 W/m2·°C (41.7%), at 0.0° of inclination, into the range we studied of the (TiTa)/G. A critical angle was found between 30° and 45° of inclination for each case of (TiTa)/G.
The UL(β)/UL(90°) vs. β correlation for the four different values of (TiTa)/G at Qu(β) > 0 is shown in Figure 4. As seen, changing β from 90° to 0°, a significant growth of UL(β)/UL(90°) ranging from 1.12 to 1.21 (8.0%) was reached at β = 0. The critical angle was also found between 30° and 45° of inclination, which is similar for all the values of the (TiTa)/G, while the variation between 0°–30° and 45°–90° seems to be almost linear behavior.

3.1.2. Case 2: (ToTi) = 0, (Qu(β) = 0)

Figure 5 shows UL vs. β and (TiTa)/G at its corresponding average of Tp. The experimental uncertainty was only ±0.07 W/m2·°C on average, 247% less than in Case 1. The most important reduction of UL(β) was for lower values of (TiTa)/G, from 8.42 to 7.63 W/m2·°C (10.4%), increasing the inclination angle from 0° to 90° at a constant (TiTa)/G of 0.124. As seen in Figure 3 and Figure 5, there is higher linearity at (ToTi) = 0 than when (ToTi) > 0, which can be due to the even and uneven surface temperature, which causes a transition flow within the cavity.
Figure 6 shows UL(β)/UL(90°) vs. β, which ranges from 1.09 to 1.11 only. The UL(0) could only be increased up to 1.8% of the value of UL(90), from the highest to lowest values of (TiTa)/G at β = 0.

3.1.3. Comparison with Previous Works

Figure 7 shows a comparison of UL(β)/UL(90°) vs. β for Case 1 (Qu(β) > 0), considering that UtUL, according Duffie and Beckman [3] and Cooper et al. [8], to calculate Ut. The Hollands correlation [23] was used to calculate the Nussetl number in both methods. Significant changes of UL(β)/UL(90°) are evident up to 10.0%, comparing different results with different types of collectors and experimental conditions.
According to the uncertainty propagation method [23], in Case 2 the experimental uncertainty of UL was 0.07 W/m2·°C, which was 247% lower than the value obtained in Case 1. The reduction in uncertainty was reached due to the elimination of Qu(β) in Equation (2). The elimination of Qu(β) implied that (ToTi) = 0, which caused the absorber plate not to have significant temperature changes through the raising tubes. Also, the Joule effect controlled by PID allows us to achieve lower uncertainty, but in Case 1 the greatest contribution of uncertainty continues to be the uncertainty of the mass flow rate.
In Case 1, where the temperature profile of the raising tubes of the collector changes significantly, the UL is considerably sensitivity to the β and (TiTa)/G, reaching up to 19.2% and 41.7%, respectively. The most significant change of UL(β)/UL(90°) vs. β was 8.0%, while for Case 2, where the raising tubes do not have a significant temperature profile, the maximum change of UL(0)/UL(90°) vs. β was only 1.8%. On the other hand, the comparison of the results with different authors showed that there are still considerable differences.

3.2. Efficiency vs. β and (Ti − Ta)/G

Figure 8 shows the thermal efficiency η vs. (TiTa)/G at β (0°, 30°, 45°, 60° and 90°). Within the range we studied, the variation of the efficiency with respect to (TiTa)/G reached up to 0.31–0.45 (45%). Similarly, the variation of the efficiency with respect to β reached up to 0.37–0.45 (21.6%). According to the slope of each linear approach, the FRUL(β) at each inclination angle was 3.12, 3.27, 3.38, 3.52 and 3.65, respectively. These variations behave in almost a linear manner over the inclination range, as in Equation (4), changing 17.6%.
F R U L ( β ) = 3.112 + 0.0061 β
As expected, the efficiency slowed down as β and (TiTa)/G increased, showing average variations of 21.6% and 45.0%, respectively, over the studied range. According to the least squares fitting method, considering double fitting, the efficiency curve in terms of β and (TiTa)/G is equated in Equation (5). The RMSE and R2 were 0.008 and 0.982, respectively, taking into account the experimental data.
η ( β , [ T i T a G ] ) = 0.5282 3.386 [ T i T a G ]   + 0.0008145 β
Equation (5) allows us to observe that the heat transfer convection between the absorber plate and glazing cover is significantly affected by changes of β and (TiTa)/G, which in turn significantly affects the accuracy of the overall heat transfer coefficient and the thermal efficiency of the flat plate collectors.

4. Conclusions

The effects of varying the angle of inclination are reflected directly in the overall loss coefficient which in turn significantly affects the thermal efficiency. Within the range we studied, the average variation of the efficiency with respect to β and (TiTa)/G was 21.6% and 45.0%, respectively. At the same time, the UL is also considerably sensitivity to the β and (TiTa)/G, reaching up to 19.2% and 41.7%, respectively. A two-fitting variable correlation was obtained from the efficiency with respect to the (TiTa)/G and β, with RMSE and R2 values of 0.008 and 0.982, respectively.
The most significant changes of UL(β)/UL(90°) vs. β were found for Case 1: (ToTi) > 0, 8.0%, where the temperature profile of the raising tubes of the collector changes significantly. On the other hand, for Case 2: (ToTi) = 0, where the raising tubes do not have a significant temperature profile, the maximum change of UL(β)/UL(90°) vs. β was 1.8% only, which is negligible. A critical angle was found between 30°and 45° of the collector’s inclination, which is similar for all the values of the (TiTa)/G, while the variation between 0°–30° and 45°–90° seems to be almost linear in its behavior.
The FRUL(β) varied up to 17.6% from the horizontal to vertical position. These variations behave almost linearly over the inclination range with respect to the average value. Therefore, the effects of the changes of β considerably influence the efficiency calculations of solar collectors if changes of the convective flow patterns within collector are not considered.

Acknowledgments

The authors are grateful to Consejo Nacional de Ciencia y Tecnolgía, CONACyT and Tecnológico Nacional de México, TecNM, whose financial support made this work possible.

Author Contributions

Orlando Montoya-Marquez and José Jasson Flores-Prieto conceived and designed the experiments; Orlando Montoya-Marquez performed the experiments; both authors analyzed the data and contributed reagents/materials/analysis tools; also, Orlando Montoya-Marquez and José Jasson Flores-Prieto wrote the paper.

Conflicts of Interest

The authors declare that they have no conflict of interest.

Nomenclature

VariablesDescriptionUnits
ACollector aream2
CpSpecific heatJ/kg°C
FRRemoval factor-
GSolar radiationW/m2
m ˙ Mass flowkg/s
QiInput heatW
QlLoss heatW
QuUseful heatW
RMSERoot mean square error-
R2Coefficient of determination-
TaAmbient Temperature°C
TiInput temperature°C
ToOutput temperature°C
TpMean absorber plate temperature°C
ULOverall heat transfer coefficientW/m2·°C
VIElectric powerW
Symbols
αAbsortance-
βTilt angle°
τTransmittance-
ηEfficiency-
Acronyms
ASHRAEAmerican Society of Heating Refrigerating and Air Conditioning Engineers
ANSIAmerican National Standard Institute
IAMIncident Angle Modifier
IEAInternational Energy Agency
CIECommission Internationale de L´Eclairage
ISOInternational organization for standardization

References

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Figure 1. Physical model.
Figure 1. Physical model.
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Figure 2. Experimental Setup.
Figure 2. Experimental Setup.
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Figure 3. UL vs. β, for variable (TiTa)/G at its corresponding Tp, at Qu(β) > 0.
Figure 3. UL vs. β, for variable (TiTa)/G at its corresponding Tp, at Qu(β) > 0.
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Figure 4. UL)/UL(90°) vs. β and (TiTa)/G, for Case 1, at Qu(β) > 0.
Figure 4. UL)/UL(90°) vs. β and (TiTa)/G, for Case 1, at Qu(β) > 0.
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Figure 5. UL vs. β, for variable (TiTa)/G at its corresponding Tp, at Qu(β) = 0.
Figure 5. UL vs. β, for variable (TiTa)/G at its corresponding Tp, at Qu(β) = 0.
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Figure 6. UL(β)/UL(90°) vs. β and (TiTa)/G, at (ToTi) = 0.
Figure 6. UL(β)/UL(90°) vs. β and (TiTa)/G, at (ToTi) = 0.
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Figure 7. Comparison of UL(β)/UL(90°) vs. β and (TiTa)/G at (ToTi) > 0.
Figure 7. Comparison of UL(β)/UL(90°) vs. β and (TiTa)/G at (ToTi) > 0.
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Figure 8. η vs. β and (TiTa)/G.
Figure 8. η vs. β and (TiTa)/G.
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Table 1. Construction specifications of the solar collector.
Table 1. Construction specifications of the solar collector.
ParameterDimensionUnits
Aspect ratio of enclosure40-
Copper absorber area1.95 × 0.95m
Fin width0.19m
Diameter of heaters 0.0381m
Diameter of reassign tubes0.0127m
Fin thickness0.5mm
Absortance0.94-
Fiber glass insulation0.0254m
Cover of glass shit 3.0mm
Table 2. Experimental conditions for the two study cases.
Table 2. Experimental conditions for the two study cases.
ParameterUnitsCase 1Case 2
βgrades0, 30, 45, 60, 900, 30, 45, 60, 90
(ToTi) °C>0=0
Qu(β)W>0=0
VIWconstantAdjustable
(TiTa)/G(m2·°C/W)0.044, 0.056, 0.070, 0.083 0.124, 0.140, 0.160, 0.195, 0.235
Ti°C60.0, 70.0, 80.0, 90.060, 70, 80, 90, 100
Tp°C66.8, 76.1, 85.3, 94.460, 70, 80, 90, 100
m ˙ kg/s0.0160.016

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MDPI and ACS Style

Montoya-Marquez, O.; Flores-Prieto, J.J. The Effect of the Angle of Inclination on the Efficiency in a Medium-Temperature Flat Plate Solar Collector. Energies 2017, 10, 71. https://doi.org/10.3390/en10010071

AMA Style

Montoya-Marquez O, Flores-Prieto JJ. The Effect of the Angle of Inclination on the Efficiency in a Medium-Temperature Flat Plate Solar Collector. Energies. 2017; 10(1):71. https://doi.org/10.3390/en10010071

Chicago/Turabian Style

Montoya-Marquez, Orlando, and José Jasson Flores-Prieto. 2017. "The Effect of the Angle of Inclination on the Efficiency in a Medium-Temperature Flat Plate Solar Collector" Energies 10, no. 1: 71. https://doi.org/10.3390/en10010071

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