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www.etasr.com Ben Khedher: Experimental Evaluation of a Flat Plate Solar Collector Under Hail City Climate 
 

Experimental Evaluation of a Flat Plate Solar 
Collector Under Hail City Climate  

 

Nidhal Ben Khedher  
Mechanical Engineering Department 

College of Engineering, Hail University 
Hail, Saudi Arabia 

N.khedher@uoh.edu.sa 
Laboratoire d'Études des Systèmes Thermiques et Énergétiques 

Ecole Nationale d'Ingénieurs de Monastir 
University of Monastir 

Monastir, Tunisia 
 

 
Abstract—Flat plate solar water heaters are widely used for water 
heating in low-temperature residential applications. In this paper 
the thermal performance of a solar flat plate water heater under 
Hail weather conditions (latitude 27°52΄N longitude  41°69΄E) was 
experimentally investigated. Fluid was circulated through the 
imbedded copper tubes in the flat plate collector and inlet and 
outlet temperatures of the fluid were noted at five minute 
intervals. The experimental-time was between 9:00AM-15:00PM. 
A study was carried out experimentally to present the efficiency 
curves of a flat plate solar collector at different flow rates. 
ASHRAE standard 93-2003 was followed for calculation of 
instantaneous efficiency of solar collector. Result shows that the 
flow rate of the circulating fluid highly influence the thermal 
efficiency of the solar collector. Optimum flow rate of 2.5L/min 
leads to maximum collector efficiency. 

Keywords-flat plate solar collector; low rate; thermal efficiency; 
ASHRAE standard 93-2003 

I. INTRODUCTION  
Solar energy is becoming an alternative for the limited 

fossil fuel resources. The recent increased interest in renewable 
energy has created a need for research in the area of solar 
technology. One of the simplest and most direct applications of 
this energy is the conversion of solar radiation into heat. Solar 
radiation can be widely used for water heating in hot water 
systems, as well as a supporting energy source for central 
heating installations. The energy of the solar radiation is in this 
case converted to heat with the use of solar panels. Using the 
sun's energy to heat water is not a new idea. More than one 
hundred years ago, black painted water tanks were used as 
simple solar water heaters in a number of countries. However, 
the solar water heating technology has greatly improved during 
the past century. Today there are more than 30 million square 
meters of solar collectors installed around the globe. Most solar 
water heating systems for buildings have two main parts: a 
solar collector and a storage tank. A flat plate solar collector [1-
3] is the most popular solar energy based device which absorbs 
the heat of sun rays through its body (usually with black color 
for maximum absorption) and then transfers the absorbed heat 

to the working fluid for raising its temperature. The efficiency 
of flat plate solar collectors as a group of water heaters depends 
on many factors such as climate conditions (especially solar 
radiation intensity), materials and design of collector as well as 
the working fluid type and mass flux rate. Authors in [4] 
reviewed applications of nanofluid in evacuated tube and flat 
plate solar collectors from efficiency, economic and 
environmental considerations and concluded that nanofluids 
offer a better alternative to conventional fluid. Authors in [5] 
presented theoretically and experimentally the enhancement of 
heat transfer to the working fluid with a metal porous medium 
placed inside pipes. The metallic mesh inserted in the collector, 
provided a higher water temperature compared to the 
conventional collector and it is the presence of the aluminum 
mesh inside the channels that distributes heat more evenly. 
Author in [6] investigated experimentally the design of flat-
plate solar collector system. In [7], authors presented an 
experimental analysis and a thermal and hydrodynamic 
modelling of a newly designed flat-plate solar collector 
characterized by its corrugated channel and by the high surface 
area directly in contact with the heat transport fluid. Authors in 
[8] studied the effect of nanofluids on the performance of solar 
collector and solar water heater from efficiency, economy and 
environmental points of view. Authors in [2] reviewed 
advancements made in the field of solar thermal technology 
with emphasis on techniques employed for performance 
augmentation. For a sunny country like Saudi Arabia it is very 
important to use the sun as main source of energy in many 
ways such as heating applications and generating electricity. In 
our study we will evaluate the thermal efficiency of a flat plate 
solar collector during winter season at four flow rates. The 
collector is working in closed loop where the water is stored in 
a tank and it is controlled to evaluate the stored heat. 

II. EXPERIMENTATION AND METHODOLOGICAL APPROACH  

A. Experiments on Solar Collector 
The experiments on the flat plate solar collector were 

carried out in Hail city (latitude 27°52’N longitude  41°69’E). 



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www.etasr.com Ben Khedher: Experimental Evaluation of a Flat Plate Solar Collector Under Hail City Climate 
 

The collector type is TE39 collector provided by TecQuipment. 
Figures 1 and 2 illustrate a schematic of the experimental set-
up, and a photograph of the flat plate solar collector, 
respectively. The collector specifications are given in Table I. 
The main part of the TE39 flat plate solar energy collector is a 

modern solar collector panel, it is two sheets of preformed 
stainless steel welded together to form integral parallel water 
channels. An airtight box with a clear acrylic cover encloses 
the surface of the panel. A thick layer of insulating material on 
the back of the panel reduces heat loss to the rear. 

 

  
Fig. 1.  Schematic of the experimental set-up. 

TABLE I.  EXPERIMENTAL SETUP DESCRIPTION 

Item Details 

Type Single pass flat plate solar energy heat absorber 

Overall Size Maximum 1500mm Height x 2400mm Length x 110mm Depth 
Collector  

Cover Acrylic -1 
Overall Dimensions 1.8m2 

Effective Surface Area 1.6m2 
Maximum Water Inlet 

Pressure 3bar 

Pump Type Mains powered, centrifugal Energy Input to Water 55W 
 

In order to determine the performance of the prototype 
under various conditions, the apparatus was equipped with the 
necessary instrumentation. A schematic diagram of the 
apparatus is shown in Figure 1, demonstrating the positioning 
of the instrumentation within the prototype. An electrical pump 
circulates the working fluid. A heat exchanger transfers heat 
energy from the solar collector to the tank which has a capacity 
of 30L. A flow sensor measures the fluid flow rate. A simple 
valve was installed to control the flow rate. A series of 
thermocouples type K were fitted on the collector (with 
accuracy of ±0.1°C), measuring the temperature of the working 
fluid in the collector at the inlet Ti and outlet To, the ambient 
temperature Ta and the stored water temperature Th. The solar 
radiation G was measured by a solar meter with accuracy of 
±2%. The solar collector was set to angle of inclination equal to 
that of Hail. 

 

 
Fig. 2.  Picture of the set-up. 

In the current study, the instruction given in ASHRAE 
standard 93-2003 [9] has been implemented to evaluate the 
thermal performance of the solar collector. The purpose of this 
standard is to test the thermal performance of solar collectors 
that use single-phase fluids. The experiments were performed 
from 9AM to 3PM (local time) on several days in January 
2018. The best data satisfying conditions of ASHRAE standard 
have been taken. Experimental results are expressed in the form 
of graphs that indicate the collector efficiency against a 
reduced temperature parameter [(Ti–Ta)/G]. The efficiency of 
solar collector was examined at various flow rates of 1.5, 2, 2.5 



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www.etasr.com Ben Khedher: Experimental Evaluation of a Flat Plate Solar Collector Under Hail City Climate 
 

and 3L/min. All the tested runs were collected using acquisition 
card system (Figure 3). Moreover, we designed the coil tank to 
store the hot water and to evaluate the solar collector working 
in a closed loop (Figure 4). The coil heat exchanger is made 
from copper. 

 

 
Fig. 3.  Data acquisition of the experimental setup. 

 
Fig. 4.  The designed coil tank. 

B. Testing Method 
Based on the ASHRAE standard 93-2003 [9], the thermal 

performance of the solar collector is evaluated. If G is the 
intensity of solar radiation, in W/m2, incident on the aperture 
plane of the solar collector having a collector surface area of 
Am2, then the amount of solar radiation received by the 
collector is:  

QiGA  (1) 

However, a part of this radiation is reflected back to the 
sky, another component is absorbed by the glazing and the rest 
is transmitted through the glazing and reaches the absorber 
plate as short wave radiation. Therefore the conversion factor 
indicates the percentage of the solar rays penetrating the 
transparent cover of the collector (transmission) and the 
percentage being absorbed. Basically, it is the product of the 
rate of transmission τ of the cover and the absorption rate α of 
the absorber. Thus, 

QiGA  (2) 

As the collector absorbs heat its temperature is getting 
higher than that of the surrounding and heat is lost to the 
atmosphere by convection and radiation. The rate of heat loss 
(Qo) depends on the collector overall heat transfer coefficient 
(UL) and the collector temperature.  

= −    (3) 
Thus, the rate of useful energy extracted by the collector 

(Qu), expressed as a rate of extraction under steady state 
conditions, is proportional to the rate of useful energy absorbed 
by the collector, minus the amount lost by the collector to its 
surroundings. This is expressed as follows:  

0 ( )u i L c aQ Q Q G A U T T      (4) 

It is also known that the rate of extraction of heat from the 
collector may be measured by means of the amount of heat 
carried away in the fluid passed through it, that is:  =  −     (5) 

Equation (4) proves to be somewhat inconvenient because 
of the difficulty in defining the collector average temperature. 
It is convenient to define a quantity that relates the actual useful 
energy gain of a collector to the useful gain if the whole 
collector surface were at the fluid inlet temperature. This 
quantity is known as “the collector heat removal factor (FR)” 
and is expressed as: =      (6) 

The maximum possible useful energy gain in a solar 
collector occurs when the whole collector is at the inlet fluid 
temperature. The actual useful energy gain Qu, is found by 
multiplying the collector heat removal factor FR by the 
maximum possible useful energy gain. This allows the 
rewriting of (4): = − −   (7) 

Equation (7) is a widely used relationship for measuring 
collector energy gain and is generally known as the “Hottel-
Whillier-Bliss equation”. The collector efficiency η is defined 
as the ratio of the useful energy gain Qu to the incident solar 
energy over a particular time period: 

The thermal performance of the solar collector is checked 
by determining the values of instantaneous efficiency for 
different combinations of incident radiation, ambient 
temperature, and inlet fluid temperature. The instantaneous 
efficiency is defined as the ratio of useful energy gain to the 
solar energy received by absorber plate of the collector. The 
instantaneous thermal efficiency of the collector is: =    (8) η =     (9) =  −  (10) 

If it is assumed that FR, τ, α, UL are constants for a given 
collector and flow rate, then the efficiency is a linear function 
of the three parameters defining the operating condition: Solar 
irradiance (G), fluid inlet temperature (Ti) and ambient air 
temperature (Ta). Thus, the performance of a flat-plate collector 
can be approximated by measuring these three parameters in 
experiments. 



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III. RESULTS AND DISCUSSION 
Experiments were carried out at the roof top of mechanical 

engineering department of the college of engineering of Hail. 
From Figure 5 it is not so easy to judge which flow rate 
ensuring the highest outlet temperature, because outlet 
temperature is highly influenced by the outdoor conditions 
(solar radiation, air temperature, wind speed). Moreover, a 
solar collector working in a closed loop it is dependent to the 
initial hot water tank temperature. As shown in Figure 6 the 
initial outlet temperatures (at 9:00AM) are different. For 
example for the case of 1.5L/min flow rate the outlet 
temperature starts from 34°C. However, it starts from 18°C for 
the case of 2.5L/min. This behavior is justified by the 
variability of weather conditions which leads to different initial 
hot water tank temperatures. The temperature of the hot water 
in the thermal storage tank depends on the effectiveness of the 
heat exchanger and the temperature difference between the 
outlet and inlet fluid. The flow rate equals to 2.5L/min 
produced the highest storage tank temperature of 82.5°C as 
shown in Figure 6. Figure 7 shows the variation of collector 
efficiency versus the reduced temperature parameter for water 
and different mass flux rates. The experimental data are fitted 
with linear equations to obtain the characteristic parameters of 
the collector and having better judgment about the effect of 
flow rate on the thermal efficiency. As it can be seen, at a given 
value of reduced temperature parameter, with increasing flow 
rate, the efficiency increases till reaching an optimum value 
corresponding to the Flow rate 2.5L/min. Based on (5) and (6), 
the useful heat energy rate increases with an increase in mass 
flux, on the other hand, useful heat energy rate is directly 
proportional to efficiency. Therefore, the efficiency increases 
with increasing mass flux. With increasing Vol. flow rate from 
1.5L/min to 2.5L/min the maximum enhancement in efficiency 
was found to be about 15%. 

Table II provides more details regarding Figure 5 and the 
solar collector performance when the working fluid is water. 
This table shows the values of the removed energy parameter 
FRUL and the absorbed energy parameter FR (τα) for the four 
flow rates (1.5L/min, 2L/min, 2.5L/min, 3L/min). It is seen that 
both removed energy and absorbed energy parameters have an 
optimum value corresponding to Vol. flow rate of 2.5L/min. 
The collector efficiency η is plotted against (Ti–Ta )/G. The 
slope of this line (-FR UL) represents the rate of heat loss from 
the collector. For example, collectors with cover sheets will 
have less of a slope than those without cover sheets.  

TABLE II.  VALUES OF F U  AND F  ( ) FOR DIFFERENT FLOW RATES 
Vol. Flow rate (L/min)  ( ) ‒  

1.5 0.779228 -7.7476 
2 0.666701 -3.2787 

2.5 0.952 -13.6875 
3 0.921 -12.2477 

 

There are two interesting operating points on Figure 7. The 
first is the maximum collection efficiency, called the optical 
efficiency. This occurs when the fluid inlet temperature equals 
ambient temperature (Ti=Ta). For this condition, the ΔT/G 
value is zero and the intercept is FR(τ α). The other point of 

interest is the intercept with the ΔT/G axis. This point of 
operation can be reached when useful energy is no longer 
removed from the collector, a condition that can happen if fluid 
flow through the collector stops (power failure). In this case, 
the optical energy coming in must be equal to the heat loss, 
requiring that the temperature of the absorber increase until this 
balance occurs. This maximum temperature difference or 
“stagnation temperature” is defined by this point. For well-
insulated collectors the stagnation temperature can reach very 
high levels causing fluid boiling. 

 

 
Fig. 5.  Outlet Temperature at different flow rates. 

 
Fig. 6.  Hot stored water  at different flow rates. 

 
Fig. 7.  Solar collector efficiency curve at four flow rates for water. 



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From the optimum flow rate (2.5L/min) corresponding to 
the highest efficiency we presented in Figure 8 the solar 
radiation, ambient temperature, hot water temperature, the inlet 
and the outlet temperatures. From this figure we can notice that 
the stagnation of outlet and hot water temperatures is reached at 
1:30 PM. 

 

 
Fig. 8.  Hot Solar intensity and various temperatures of solar collector at 
flow rate 2.5L/min. 

IV. CONCLUSION 
ASHRAE standard 93-2003 was detailed, then followed for 

calculation of the efficiency of a flat plate solar collector. A 
more precise and detailed analysis should include the fact, that 
the overall heat loss coefficient (UL) and other factors as the 
heat removal factor (FR) are not constant values and they are 
tightly dependent on fluid flow rate. The present experiment 
focused on a comparative analysis of a four different flow rates 
(1.5 L/min, 2L/min, 2.5L/min, 3L/min) and their effect on the 
performance of flat plate solar collector. The experiment 
findings established that maximum efficiency, when reduced 
temperature parameter [(Ti–Ta)/G] equals to zero, was 95% for 
flow rate 2.5L/min. 

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[3] X. Xu, Y. Lei, Z. Xiaosong, P. Donggen, “Review on the Development 
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