

<4D6963726F736F667420576F7264202D20E3DECFC7E320E6DAE1ED20E6CEE1EDE120392D312D>


Al-Khwarizmi 
Engineering   

Journal 

Al-Khwarizmi Engineering Journal, Vol. 14, No. 1, March, (2018) 

P.P. 1-9 

 
Experimental Study on Solar Air Heating 
 

Miqdam T Chaichan*          Ali J. Ali**           Khaleel I. Abass*** 

* Energy and Renewable Energies Technology Center/ University of Technology/ Baghdad/ Iraq 

** Department of Biomedical Engineering/ University of Technology/ Baghdad/ Iraq 
*** Department of Mechanical Engineering/University of Technology/ Baghdad/ Iraq  

   *E-mail: 20185@uotechnology.edu.iq 

 ** E-mail: 10678@uotechnology.edu.iq 

***E-mail: 20078@uotechnology.edu.iq 

 
(Received 22 March 2017; accepted 18 July 2017) 

https://doi.org/10.22153/kej.2018.07.008 
 

Abstract  

  
A new type of solar air heater was designed, fabricated, and tested in Baghdad, Iraq winter conditions. The heater 

consists of two main parts. The horizontal section was filled with the black colored iron chip while the vertical part has 

five pipes filled with Iraqi paraffin wax. A fan was fixed at the exit of the air. Two cases were studied: when the air moved 

by natural convection and when forced convection moved it. The studied air heater has proven its effectiveness as it 

heated the air passing through it to high temperatures. The results manifest that using little air movement makes the 

temperatures, stored energies, and efficiencies of the two studied cases converge. The suitable solar intensity of Baghdad 

city makes the use of solar air heater suitable to reduce the electricity and fossil fuels consumption. 

 
Keywords: Forced convection, iron chip, PCM, paraffin wax, solar air heater. 

 
1. Introduction 
 
The demand for energy is increasing with time 

due to its massive consumption energy to meet the 
population and development's needs. The today 

power generation (whether for electricity or 

transportation) is coming mainly from fossil fuels 
like coal, oil and natural gas. The burning of these 

resources caused many environmental problems all 

over the world as global warming, acid rains, and 
the ozone hole. Today, the nation's heading 

towards the renewable and sustainable energies 

like solar energy to compensate the fossil fuels [1, 

2].     
Solar energy has many advantages compared to 

conventional fossil fuels on the environment. This 

energy is clean, abundant, and available all over the 

world. It is safe and environmental friendly [3]. 

The solar collectors for water heating have been 
used for many years with efficient operation in 

developed countries like the USA and Europe [4].  

Solar air heaters are thermal systems used to 
convert the incident solar radiation into heat used 

to warm the air. These air heaters are used today in 

many applications like space heating for comfort 
conditions, drying agricultural plants and marine 

products [5]. The use of air heater reduces the 

dependence on fossil fuels. The air heater primarily 

consists of an isolated duct for hot air, a heating 
panel, a glass cover, and an air blower for moving 

air. The group has a thermally isolated absorbing 

plate with black color in general [6]. The glass 
cover allows the solar radiation to pass through it 

and prevents its exit. This process causes the 

greenhouse effect which improves the efficiency of 


Miqdam T Chaichan                             Al-Khwarizmi Engineering Journal, Vol. 14, No. 1, P.P. 1- 9 (2018) 
 

2 

 
air heater. The glass also works as part of the air 
duct [7]. 

    However, these systems suffer from many 

problems like low convection heat transfer 
coefficient of air which reduces the thermal 

exchange between the heater and air [8, 9]. The 

absorber plate, in this case, will become hotter and 

the thermal losses will be increased through the 
covers. Many researchers tried to enhance the heat 

transfer coefficient of air and the air heater 

performance. 
Prasad et al. [10] suggested double glassing 

cover for the air heater to minimize its thermal 

losses. Sopin et al., Ozgen et al., and Chaichan et 

al. [11-13] tested a double pass channel air heater 
where the air flows from above and then below the 

absorber plate. Many researchers made many 

modifications on the air heaters to reduce its 
thermal losses and increase the air heat transfer 

coefficient like adding fins for the double pass air 

heater [14]. Also, References Lertsatitthanakorn et 
al. [15], Esen [16], Paisaran [17], and Ho et al. [18] 

studied adding fins to the absorbing plate. Qenawy 

and Mohamad [19] and Thankur et al. [20] used a 

porous material to increase the heat exchange 
inside the air heater. The porous material consisted 

of wire mesh screen. Ramadan et al. [21] used 

limestone and gravels as a porous media while El-
Sebaii et al. [22] added iron scrap to gravel and 

limestone.   

The solar heater reliance on sunlight as the only 
energy source makes its use after sunset is useless. 

Many researchers investigated the abilities to use 

thermal storage materials to increase the working 

time of the air heater. Srivastava et al. [23] used a 
phase change material (lauric acid) as a heat 

storage material. This study increased the attention 

on using of phase change materials (PCM) in air 
heaters as it elongates the working time. The 

authors fingered the importance of the charging 

and discharging of the used PCM heat transfer 

characteristics. Kabeel [24] investigated the effect 
of adding paraffin wax as a PCM for an air heater 

performance. The authors presented the weather 

parameters affecting the performance of their 
module. 

Chaichan et al. [25] used nano-Al2O3 with 

paraffin wax to enhance the charging and 
discharging process in a heat storage wall (Trombe 

wall). The authors claimed better thermal 

conductivity of nano-PCM which made the wall 

gained higher temperatures up to 29.08% 
compared to the use of paraffin wax alone. The 

addition of nano-Al2O3 to PCM made the materials 

stored temperature increased with about 42.68%.  

Iraq is characterized by bright sun of most days 
of the year, with an average of 335 days, and 

relatively high solar radiation intensity ranging 

from 245 W/m
2
 in winter to 980 W/m

2
 at summer 

[26]. These conditions make Iraq a suitable 

location for using air heaters in all its applications 

that reduce the demand on electricity which the 

country is suffering from its lack [27]. 
The aim of this study is to design, fabricate and 

test a new type of air heater. The objective is to find 

a suitable, cheap, and easy to construct the system. 
The proposed method is useful in reducing energy 

and fuel consumption, which means better 

environment and less pollution. 

 
2. Experimental Technique 
 
The new designed and made solar air heater 

consists of a horizontal passage and a vertical 
passage connected. The heater has a cubic form 

cross section with a rib length of 20 cm. Two sides 

of the heater are from isolated wood covered by a 
copper plate painted with black, while the other 

two sides are from the glass with 3 mm thickness. 

The wood is covered with a glass wool insulator 

with a 1.5 cm thickness to confirm the system 
thermal insulation. Glass has been installed on the 

wood in the gaps paved in wood, and area in 

contact between the glass and wood was filled with 
silicon to ensure no leakage of hot air from the 

system can be exist. Fig 1 shows a schematic 

diagram of the studied solar air heater with its 
dimensions.   

 
Fig. 1. a schematic diagram of the designed, 

fabricated, and studied solar air heater. 

 
Miqdam T Chaichan                             Al-Khwarizmi Engineering Journal, Vol. 14, No. 1, P.P. 1- 9 (2018) 
 

3 

 
The horizontal part of the air heater was filled 

with 3 kg of iron chip colored in non- shiny black 

to increase the absorbed radiation. In the vertical 
part of the heater, five black pipes were fixed on 

the plate. The 5 cm diameter pipes were filled with 

Iraqi paraffin wax which its specification are listed 

in Table 1. The used paraffin wax was 10 kg. The 
horizontal part of the heater was closed by a piece 

of wood has 10 holes having diameter of 1.0 cm 

each. The vertical part was mounted with a wood 
cover with an air fan has a diameter of 7.5 cm and 

power of (4 watt) to force air movement from the 

heater to the conditioned space. Fig. 2 shows a 

photo of the tested air heater.  
Four thermocouple type K were used to 

measure the temperature of the air heater parts. One 

thermocouple was fixed in the front of the entrance 
inside the chip. The second one was set at the end 

of the chip while the third was attached on one of 

the PCM pipes. The last thermocouple was fixed at 
the exit part of the heater before the fan. The air 

temperature was measured in the shadow by a 

thermometer. 

 
Fig. 2. a photo of the tested air heater 

 
Table 1,  

The specifications of the paraffin wax used  

Melting temperature (°C) 40 

Latent heat of fusion (kJ/kg) 190 
Solid specific heat (kJ/kg °C) 2.384 

Liquid specific heat (kJ/kg °C) 2.49 

The temperatures were tiled as the following: 

Ta- the ambient air temperature. 

T1- the chip temperature at the center, near the air 
entrance. 

T2- the chip temperature at the center of the 

horizontal part of the heater. 

T3- The temperature of the middle paraffin wax 
pipe, in the vertical part of the heater. 

T4- The air temperature at exist of the heater. 

The following equations were used to calculate 
the heat storage values for the air heater and its 

components.  

The storage energy inside the air heater 

�� = ���(�	
� − �	 )          (kJ)                    …(1) 
The whole day storage energy 

�	�	�� = ���� + ���� + ⋯ + ����  (kJ)      …(2) 
The energy drawn by fan 

�� = �� � ��� (���� ��	 − ���� ��)  (kW)          …(3) 
The total drawn energy 

�� ! �" = ��#$%## + ��##%#& + ⋯ + ��'%(  (kW)                             
                                                                        …(4) 
The air flow rate 

�� � = )*� +�   (kg/s)                      …(5) 
The system efficiency 

, = -�./0×2        (%)            …(6) 
Error Analysis 

 
Error analysis is used to determine the accuracy 

of the measurements and depends on the accuracy 
of readings from all the devices used in the 

experiments. In this study, the first measuring 

devices were used to measure the temperature and 
the second to measure the air speed. The two 

devices were calibrated by comparing their 

measurements with a standard device. Table 2 

gives information about the devices used and the 
rate of deviation in the readings.  

 
Table 2, 

The used measuring devices in the present study. 

Measuring parameter Device name Company Range Error rate 

Temperature Digital thermometer Comark (UK) -25 to 70°C 1.02 

Air speed Anemometer Lutron YK-

80AM 

0-15 m/s 1.32 

 
Miqdam T Chaichan                             Al-Khwarizmi Engineering Journal, Vol. 14, No. 1, P.P. 1- 9 (2018) 
 

4 

 
The results of the calibration showed that the error 

rate is calculated according to equation [28]: 

 
34 = 56 7478# 3�9
:

+ 6 7478& 3:9
:

+ ⋯ + 6 7478; 3�9
:<

=.?
                                                    

                                                                        …(7) 

34 = @(1.02): + (1.32):E=.? = 1.668 
 

The error rate was less than 5% making the 

readings acceptable geometrically. 
 

Experimental Procedure 
 
The tests on the solar air heater were conducted 

in Baghdad city-Iraq in last two weeks of Dec-2016 

and the beginning two weeks of January-2017. 

This month was selected due to its low ambient 

temperature as it has the lowest solar intensity 
compared to the other months. The system was 

fixed facing the south, and the variable 

temperatures were measured for two cases: 
1-When the air was flow by natural convection. 

2- When the air was flow by forced convection 

using the fan. 
The tests were repeated more than three times, 

and the average values were taken to ensure the 

repeatability and to reduce the impact of 

uncertainty variables.  
 

3. Results and Discussion 
 
The solar air heater starts its work with the sun 

rise in the first morning, as the sunlight heats the 

chip in spite of its low radiation intensity values. 

For this reason, the temperature T1 (35.3°C) starts 

higher than air temperature (2°C), as Figures 3 &4 
show. 

The iron chip gains heat from the sun easier and 

faster that the PCM for the period from 8 AM to 2 
PM. After this hour, the chip temperature starts to 

decline rapidly whenever the sun goes down. The 

ambient air temperature in Baghdad climate is 
small in winter. However, the suggested air heater 

proved its effectiveness as the exit air temperatures 

were very high starting from 10 AM (45°C) till it 

reached its maximal at 2 PM (65°C). 
 

Fig. 3. The distribution of the system variable parts 

temperatures with time without fan 

 
The paraffin wax starts to gain heat with a time 

lag compared to the iron chip. The thermal 
conductivity of the wax is small compared to the 

chip which causes this heat gain delay. The PCM 

temperatures increased till it reached its melting 
point, at which the increase in the wax temperature 

pause until all the wax is melted, then temperature 

continued to rise. 

 
Fig. 4. The distribution of the system variable parts 

temperatures with time without fan 

 
The wax temperature all the charging period 

(the heating time from 8 AM to 2 PM) was lower 

than the chip temperature. At the discharging time 
(from 2 PM till night) the PCM temperature was 

higher than the chip ones. The PCM stored more 

thermal energy than the chip which benefits after 

sunset as the exit air temperature was 24.5°C at 10 
PM. The resulted temperature confirm the success 

of the established system as it gathers the rapid gain 

of heat by the chip and the high stored energy 
quantity by the PCM. 


Miqdam T Chaichan                             Al-Khwarizmi Engineering Journal, Vol. 14, No. 1, P.P. 1- 9 (2018) 
 

5 

 
Figures 5 & 6 represents the measured 
temperature of the system variable parts with time 

when the air was forced to move using a fan. The 

used of the fan is crucial in this kind of systems to 
control the air mass flow rate as desired. In this 

case, the system was left to warm up till 10 AM; 

then the fan was operated. The results indicate high 

temperatures of the systems' parts that have tiny 
lower quantities compared to the free convection 

operation of the scheme. 

  
Fig. 5. The distribution of the system variable parts 

temperatures with time with fan 

 
In the case of employing a fan, the chip 

temperatures decline rapidly in the discharging 
period due to the reduction in the heat supply from 

the sun. Here, the use of PCM as a heating source 

was wise as it preserved the high air temperatures. 

The clear sky and high solar intensity of the Iraqi 
winter made these temperatures possible, which 

means that the use of such air heaters in homes and 

buildings can reduce the relay on grid electricity 
that it is generated from fossil fuels. 

 
Fig. 6. The distribution of the system variable parts 

temperatures with time with fan 

Figures 7 and 8 show the stored thermal energy 
variation with time. The stored energy of the chip 

was little compared with the paraffin wax. The 

maximum storing energy gained by the wax at the 
phase change period. The benefit of this stored 

energy appeared in elongating the air warming 

period for several hours after the heating source 

(the sun was set). 
 

Fig. 7. Stored thermal energy variation with time.  

 
Fig. 9 manifests the system's stored thermal 

energy variation with time for the two cases. The 

results indicate clear convergence for the two 
cases. The air flow rate with the fan was weak 

which manage the system parts to gain heat without 

fast cooling. The figure results support the previous 
conclusion about the system success in Iraqi winter 

weathers. 

 
Fig. 8. Stored thermal energy variation with time. 

 
Miqdam T Chaichan                             Al-Khwarizmi Engineering Journal, Vol. 14, No. 1, P.P. 1- 9 (2018) 
 

6 

 
Fig. 9. The flowing air stored energy with time 

distribution for the studied cases. 

 
Fig. 10. The system efficiency variation with time 

for the studied cases. 

 
For validation and ascertaining the quality and 
efficiency of the designed air heaters, it has been 

compared with many other devices that were tested 

in Iraq and other countries weathers. Table 3 lists 
this comparison. The table indicates that for Iraq 

the new solar air heater achieved the highest 

maximum temperature and stored energy and 
efficiency due to the use of the chip in addition to 

the PCM. For Ref. [30] the authors used in addition 

to PCM solar radiation concentrators to increase 

the incident radiation. However, the paper results 
converge with the recent study results. Ref [31] 

used square steel wire mesh with forced convection 

(air moving by a fan). The authors' designed system 
operated till 3 PM while the recent study system 

continued heating till 10 PM. 

 
Table 3, 

A comparison between the present study and other published researches. 

Reference Location System type 
Max. Temp. 

achieved 

Max. stored 

energy achieved 

Max. eff. 

achieved 

Present 

study 
Iraq Chip and PCM 74°C 2100 kJ 36% 

Chaichan et 

al. [25] 
Iraq PCM only 60°C 1300 kJ - 

Chaichan et 
al. [29] 

Iraq Water 48°C - - 

Chaichan et 

al. [13] 
Iraq Aluminum plate 50°C 1000 kJ - 

El-Khadraui 

et al [29 ] 
Tunisia PCM 90°C 1900 kJ 32.85% 

Roy et al. 

[30] 
Bangladesh Square wire mesh 52°C 6465 kJ 54% 

 
4. Conclusions 
 
In this study, a new design of solar air heater 

was fabricated and designed in Iraqi winter 

weathers. In this design iron chip and PCM were 
used to gain heat from the solar rays. Two cases 

were tested when the air passed through the air 
heater in natural convection and forced convection.  

The resulted air temperatures explicit an 

increase after passing through the heater. The chip 
was useful in increasing the air temperature due to 

its high surface area of contact. The paraffin wax 

was a good choice as it increased the system 

warming time for more than four hours after sunset. 


Miqdam T Chaichan                             Al-Khwarizmi Engineering Journal, Vol. 14, No. 1, P.P. 1- 9 (2018) 
 

7 

 
The results reveal that using a fan with low flow 
rate reduces the gained temperatures and stored 

energy but in a limited amount. The produced 

efficiencies in the two tested cases were 
convergence. The suggested system in spite of it 

was a prototype it confirmed its ability to warm 

Iraqi houses and building for a period that can 

exceed 14 hours/day. The use of such solar air 
heaters will reduce the amount of electricity and 

fuel consumption in winter. 

 
Nomenclature 

 
A   

 
The heater 

area 
 

Cpwax wax specific heat (kJ/kg. h) 
HI
H*� 

The partial derivative 

34 Uncertainty in the results 
m� KLM  air drawn (kg/s) 
mwax   wax mass (kg) 

Qs1  energy stored in the chip (kJ) 

Qu the drawn energy from the heater   
(kJ) 

Tairout the delivered air temperature (K) 

ρa air density (kg/m
3
) 

Cpchip chip specific heat (kJ/kg. h) 

Cpa air specific heat (kJ/kg. h) 

ei Uncertainty interval in the nth 

variable. 
I Solar intensity (W/m

2
) 

mchip chip mass (kg) 

Qs  Storage energy inside the air 
heater 

Qs2  energy stored in wax (kJ) 

Q air Energy drawn by the air (kJ) 

Tairin  entering air temperature (K) 
Va Air speed (m/s) 

 
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  )2018( 1-9، صفحة 1د، العد14دجلة الخوارزمي الهندسية المجلممقدام طارق جيجان                                                               
 

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  الخالصة
  

ن. الجزء يمن جزئين رئيسسخن الهواء العراق. يتكون م -تم تصميم وتصنيع وفحص عمل نوع جديد من مسخنات الهواء الشمسية في اجواء مدينة بغداد
حة عند فتحة خروج مرواالفقي مأل برايش الحديد سوداء اللون بينما ثبتت خمسة انابيب مملوءة بمادة الشمع البرافينيي متغيرة الطور في الجزء العمودي. ثبتت 

حرك بفعل الحمل القسري.اثبت مسخن الهواء المدروس كفاءته الهواء. تمت دراسة حالتين: عندما يتحرك الهواء بفعل الحمل الطبيعي والحالة الثانية عندما يت
ات خزونة و الكفاءاذ انه سخن الهواء المار خالله الى درجات حرارة عالية. بينت النتائج ان تحريك الهواء بسرع منخفضة يجعل درجات الحرارة والطاقات الم

اد مناسبه جدا الستخدام مسخنات الهواء الشمسية والتي من شأنها ان تقلل استهالك الكهرباء للحالتين المدروستين تتقارب. ان شدة االشعاع الشمسي لمدينة بغد
  والوقود االحفوري.