International Journal of Engineering Materials and Manufacture (2020) 5(1) 12-18 

https://doi.org/10.26776/ijemm.05.01.2020.03 

 

M. Rakib Uddin  and Muhammad Faiz bin Haji Ya’akub 

Electrical and Electronics Engineering Programme Area, Faculty of Engineering 

Universiti Teknologi Brunei, Brunei Darussalam 

Email: rakib.uddin@utb.edu.bn 

 

Reference: Rakib Uddin, M. and Ya’akub, M. F. (2020). Parked Car Interior Temperature Investigation in Brunei Darussalam. 

International Journal of Engineering Materials and Manufacture, 5(1), 12-18. 

 

 

Parked Car Interior Temperature Investigation in Brunei Darussalam 

 

M. Rakib Uddin, and Muhammad Faiz bin Haji Ya’akub 

 

 

Received: 04 February 2020 

Accepted: 26 March 2020 

Published: 30 March 2020 

Publisher: Deer Hill Publications 

© 2020 The Author(s) 

Creative Commons: CC BY 4.0 

 

 

ABSTRACT 

When a car is parked under the sunlight for a long period of time, solar radiation enters the vehicle through the car 

glass and becomes trapped inside the car. This causes the cabin interior air temperature to increase and this is especially 

noticeable in tropical countries with hot and humid climates that are situated near the equator like Brunei Darussalam. 

Aside from causing thermal discomfort to the passengers inside the car, degradation of the surfaces of the car interior 

may also be accelerated. This paper aims to demonstrate the severity of the heat by recording a number of 

temperature measurements in a certain period of time for two different types of cars, under three different conditions 

for each car and comparing them to the ambient temperature. It is observed that the interior temperature depends 

on the design of the car. We experimented temperature measurements for two types of car models, i.e., saloon and 

SUV models. Saloon car is design such as way that its interior volumes space is smaller than the SUV designed car. 

The smaller interior volume spaced Saloon car exhibits higher maximum temperature of 68.7°C whereas the larger 

interior volume spaced SUV car exhibits maximum temperature of 59.4°C under fully exposed to sun with same 

environmental conditions. 

 

Keywords: Car interior air temperature; ambient temperature; thermal discomfort 

 

1 INTRODUCTION 

Prolong exposure to sunlight can significantly increase the temperature inside a parked car when the car’s engine is 

off. This is due to the solar radiation that enters the vehicle through the window panels and becomes partially trapped 

within the cabin of the car. This causes the temperature to rise substantially when the occupants get back into the 

parked car. The main issue that comes from the highly elevated temperature is thermal discomfort to the passengers. 

Aside from that, it may also accelerate the degradation of the surfaces of the car interior after being exposed to 

sunlight for so long and are subjected to stress from the increasing heat. The main purpose of this investigation is to 

find out the variation of interior air temperature in relation to the ambient temperature with respect to time. To 

prove that the interior air temperature of the vehicle does indeed rise significantly, a series of tests has been devised 

to monitor and gather some data from inside two different types of cars, under three different conditions of each 

car. The objectives of this paper are to; take multiple measurements of the interior air temperature of the car within 

certain period of time of the day; repeat the process for different types of sunlight exposure and for different types 

of cars; investigate the relationship of the interior air temperature variation in relation to the ambient temperature 

outside the car by graphically showing the characteristics. 

In May 2014, W. A. A. Fadeel et al, has made a journal about Temperature Variations in a Parked Car Exposed to 

Direct Sun during Hot and Dry Climates in Aswan, Egypt [1]. They have concluded that the temperature levels inside 

a parked car can increase to as much as 80 °C. In a similar study, M.S.F. Mansor et al. [2] concluded that the trapped 

and accumulated heat causes the temperature inside a car to reach up to 50 ̊C. This has caused many fatalities being 

reported as a result of internal car heat. Russell Manning and John Ewing had also made a report about Temperature 

in Cars survey [3]. Their report touches on several ways of investigating the temperature of inside a car. On vehicles 

having different paint colours, they have concluded that the rate of temperature increase inside the cabin is similar, 

regardless of paint colour. On having the windows slightly open versus having it fully closed, it was concluded that 

the peak temperature was still dangerously high for both cases but the one with windows slightly open has a slower 

temperature rise inside the cabin of the car. Lastly, their temperature investigation also include the use of sunshades 

and tinted films inside the test car, which both results in only an insignificant difference to the rate of temperature 

rise with only a marginal difference to the final peak cabin temperatures.  

M. Pešek, Brno University of Technology has made an article about The Temperature field’s measurement of air in 



Rakib Uddin and Ya’akub (2020): International Journal of Engineering Materials and Manufacture, 5(1), 12-18 

13 

the car cabin by infrared camera [4]. In October 2013, Sudhir Chitrapady Vishweshwara et al. made a journal about 

the Study of Excessive Cabin Temperatures of the Car Parked in Oman and its Mitigation [5]. Their study has 

concluded that on a bright sunny day, the vehicles cabin temperature rises to about 22°C above ambient temperature. 

However, upon installing the mitigation, the difference between cabin and outside temperature was greatly reduced. 

In August 2015, an independent test was carried out by Doug DeMuro on the impact of car colour to the interior 

temperature [6]. In the heat, the colour of the car can have an impact: with black cars heating up quicker and cooling 

down slower than white ones. The black car's cabin measured a scorching 130 ̊F (54°C), while the white car's interior 

registered only 113 ̊F (45°C). He discovered that the interior of the white car cooled to 84 ̊F (29°C) after 10 minutes 

of turning the air-conditioning back on, while the black car was still at 91 ̊F (27°C). Another study by H. H. Al-Kayiem 

et al [7], mentioned that the thermal condition inside the car forces the car user to wait 2-5 minutes to cool down 

the hot interior air and this increases fuel consumption. Several studies also found that the heat inside the car can 

cause health concerns as mentioned in the findings by C. McLaren et al [8] and A. Grundstein et al. [9]. 

In this paper, we aim to demonstrate the severity of the heat by recording a number of temperature measurements 

in a certain period of time for two different types of cars, under three different conditions for each car and comparing 

them to the ambient temperature in Brunei Darussalam. We found that the interior air temperature can reach a 

maximum of 68.7°C when the car is fully exposed to sunlight. Even when the car is fully shaded from the top, the 

temperature can reach a high of 43°C. The rest of the paper is organized as below: in section 2, the temperature 

measurement investigation setup is described. In section 3 of this paper, the analysis of temperature investigation 

data was explained. Lastly, section 4 describes the conclusion of this paper. 

 

2 TEMPERATURE INVESTIGATION SETUP 

To investigate the temperature characteristics, specialised equipment and proper steps and procedure is needed. 

 

2.1 Device under Testing 

The test cars used were a black coloured 2010 Ford Fiesta for the Saloon experiment and a light-green coloured 2004 

Ssangyong Rexton for the SUV experiment. The Ford Fiesta is a compact saloon/sedan type of car that can 

accommodate 5 people, while the Ssangyong Rexton is a Large-size 7-seater SUV that has a very large cabin size, as 

shown in Fig 1 and 2. 

 

 

Figure 1. Schematic of a 2010 Ford Fiesta saloon (dimensions are in mm) 

 

 

 

 

Figure 2. Schematic of a 2004 Ssangyong Rexton SUV (dimensions are in mm)   

2489

4291

1
4

9
6

1722

All measurements in millimetres.

2830

4730

1
7
7
0

1880

All measurements in millimetres.



Parked Car Interior Temperature Investigation in Brunei Darussalam 

14 

2.2 Measuring Equipment 

The test was carried out using a temperature data logger made by the company Elitech. Officially called the Elitech 

USB Temperature Data Logger RC-5, it has a wide measuring range of -30°C to 70°C, with a resolution of 0.1°C and 

an accuracy of ±0.5°C. It uses an internal NTC thermal resistor as its sensor as the unit itself is IP67 rated water 

resistance. The RC-5 can automatically gather temperature data over a set amount of time and can be transferred 

using the built-in USB connection. The main reason for using this specific equipment is due to its wide temperature 

range and robust hardware, which makes it very suitable for this application. The data logger is also specialised for 

measuring temperature inside a confined or enclosed space such as a room or a car. 

 

2.3 Test Area and Period 

The cars were tested at a private and open land area in located in Bandar Seri Begawan, Brunei Darussalam. The 

location has a very large open space that can ensure that the tested cars are not shaded when the temperature is 

logged. The test was carried out at random days where there was generally sunlight throughout the day from 9 AM 

to 5 PM for each day, from December of 2017 until the March of 2018. 

 

3 EXPERIMENTAL METHOD 

Before carrying out the temperature measurements, the RC-5 data logger’s parameters must be set using a computer 

through the given proprietary software by Elitech. First, both the RC-5 data loggers must be calibrated properly. 

Although they are claimed to be pre-calibrated by Elitech from the factory, sometimes they have some little tolerance 

that can cause some discrepancy. In this case, the data logger was then calibrated using the given proprietary software 

using a known already calibrated SHTC1 sensor as a basis of control. This is shown in Fig 4 and 5. Next, the measuring 

parameters are then set using the same software. In this case, the real-time clock was synced with the correct time on 

the computer and the time interval was then set for 5 minutes. This means that the data logger will automatically 

record and save the current temperature every 5 minutes.  

The RC-5 data logger was then put inside the car and was suspended by a small rope in the approximate centre 

of the interior between the font seats of the car as to avoid contact with the interior surfaces. This is shown in Fig 6. 

The purpose of this is for measuring only the interior air temperature of the vehicle, rather than surface temperature 

of the car interior. It was placed inside the car for at least 10 to 15 minutes before 9AM to ensure that the air 

temperature inside the car settles down after the door was being opened for the installation of the data logger. The 

data logger was kept inside the car for the total duration of 8 hours. It was important to ensure that none of the 

door or windows were open throughout the whole duration. 

The tests were carried out in three different conditions for each types of cars. On Condition 1; the car was parked 

in an open area, more than 25 metres from any buildings or trees to ensure that the car will not be shaded in any 

way at any time from 9 AM to 5 PM, as shown in Fig 7. On Condition 2; the car was parked relatively near to a 

building, around less than 10 metres to the nearest building, as shown in Fig 8. In this case, the car was partially 

shaded at certain time of day, except for mid-day where the car was fully exposed and not shaded because the sun 

is directly above the car. On Condition 3; the car was parked under an open type garage or shed where the car is 

only fully shaded from the top but not from the sides or the front, as shown in Fig 9.  For each condition, at least 

five days’ worth of measurements were taken for each car for each conditions to make a sizeable sample of data. 

 

4 EXPERIMENTAL RESULTS AND ANALYSES 

To compare the temperature data obtained from the RC-5 temperature data logger, there must also be data for the 

ambient temperature during the same period of time in the day. The samples for ambient temperature were taken 

from the Weather Underground website for the hourly forecast temperatures for each day. Condition 1 can be 

considered as the worst case scenario for temperature increase because the car is fully exposed for the total duration 

of 8 hours in direct sunlight and the graph in Figure 10 reflects that. After just 1 hour from 9:00AM, the interior air 

temperature already rose by about 18.6°C (from 32ºC to 50.6ºC) which is respresents a sizable 58.1% increase. 

 

 

 

Figure 3. RC-5 Temperature Data Logger Figure 4. Calibrating and setting the time interval parameter 

Setting the record interval

Calibrating function



Rakib Uddin and Ya’akub (2020): International Journal of Engineering Materials and Manufacture, 5(1), 12-18 

15 

 
 

Figure 5. Calibrated data logger Figure 6. Placement of equipment inside the car 

 

 

 

 
 

Figure 7. Condition 1, car is fully exposed to sunlight and 

located more than 25 m from any buildings 

Figure 8. Condition 2, car is partially shaded at certain 

times and located less than 10 m from any buildings 

 

 

 

 

Figure 9. Condition 3, car is shaded under open type shed 

 

Also by observing the graph, the interior air temperature usually reached within 10% of the maximum at around 

1:00PM and stays about constant until around 4:00PM where the temperature starts to fall off because the decrease 

in sunlight intensity. The highest interior air temperature of 68.7°C obtained was on March 23 and 24 at exactly 2:30 

PM. At that exact time, the ambient temperature was 31°C and when compared with the interior air temperature of 

68.7°C, the percentage difference was a significant 45.1%. As for the case of the SUV type car for Condition 1 as 

shown in Fig 11, the initial interior air temperature seems to start of higher than that from the Saloon type car. This 

may be due to the bigger surface area of the windows of the SUV which leads to more sunlight entering the car 

especially during the morning since the data logger may be subjected from direct sunlight. The interior temperature 

generally reached maximum at around 2:00PM, which was similar to that of the Saloon. However, the maximum 

temperature of 59.4°C was much lower than that from the Saloon (68.7°C). 

As for Condition 2 as shown in Fig 12, the interior air temperature was very close to the outside ambient 

temperature even after 2 hours, from 9:00AM to 11:00AM. Only after 11:00AM does the interior air temperature 

saw a sharp increase as the car was being directly exposed to the sun approaching midday. The maximum interior 

air temperature was usually reached at around 1:00PM to 2:00PM. From then onwards, the temperature starts to 

slowly decrease and then at around 4:00PM, the interior temperature starts to cool down quickly. The maximum 

interior air temperature reached was 57.6°C. 

Buildings

or 

Trees

>25m

Buildings

or 

Trees

<10m



Parked Car Interior Temperature Investigation in Brunei Darussalam 

16 

 

Figure 10. Condition 1 for Saloon type 

 

 

Figure 11. Condition 1 for SUV type 

 

 

Figure 12. Condition 2 for Saloon type   



Rakib Uddin and Ya’akub (2020): International Journal of Engineering Materials and Manufacture, 5(1), 12-18 

17 

For the SUV type in Condition 2, the characteristic was similar to that of the Saloon but generally reaches its maximum 

interior air temperature a little later at around past 2:00PM. Again the interior temperature saw a sharp decrease in 

temperature after 4:00PM. The maximum interior air temperature reached was 57.1ºC, about the same with the 

Saloon. This is shown in Fig 13. For Condition 3, the rise in interior air temperature was significantly slower when 

compared to Condition 1 and 2. In some cases, it could take up to 2 hours to even exceed 30ºC as seen in Figure 14. 

Looking at the graphs for January 17, the interior air temperature reached its maximum at the same time as the 

ambient temperature, but even at its peak there was only a mere 6.2% difference. The maximum interior air 

temperature reached was 34.1ºC. 

As for the SUV in Condition 3 as shown in Fig 15, the initial rise has similar characteristics to that of the Saloon, 

however the interior air temperature inside the SUV kept on rising and generally hits the peak around after 3:00PM. 

The continued rise in temperature might be caused by the bigger surface area of the window panels of the SUV, 

which allows reflected sunlight to enter the car from the sides even when the car is fully shaded from the top. Then 

as with all the other Conditions, the temperature drops significantly after 4:00PM, the same can be said for the 

ambient temperature as well. When compared to the Saloon in the same conditions, while the Saloon’s interior air 

temperature stays generally constant after 1:00PM, the SUV’s interior temperature kept on rising, reaching a 

maximum of 43ºC, which is a significant 28% percentage difference compared to the ambient temperature.   

 

 

 

Figure 13. Condition 2 for SUV type 

 

 

Figure 14. Condition 3 for Saloon type   



Parked Car Interior Temperature Investigation in Brunei Darussalam 

18 

 

Figure15. Condition 3 for SUV type 

 

5 CONCLUSIONS 

The temperature investigation has been performed in three different conditions; fully shaded from the top, partially 

shaded and fully exposed to sunlight. When the cars were fully shaded from the top, the Saloon and the SUV reached 

34.1ºC and 43ºC respectively. The reason of the SUV having a higher maximum temperature might be due to the 

bigger surface area of the windows of the SUV which leads to more sunlight entering the car especially around 

afternoon since the data logger was  subjected to direct sunlight. When the car was partially shaded, the Saloon and 

the SUV reached 57.6ºC and 57.1ºC respectively. While they both  achieved similar maximum temperature when 

being partially shaded, it should be noted that the rate of increase of interior air temperature was lower for the SUV. 

Lastly, when the car is fully exposed to sunlight, the Saloon and the SUV reached 68.7ºC and 59.4ºC respectively. 

Both the maximum temperature was very high, but the maximum temperature of the Saloon was significantly higher. 

This may be due to the Saloon having less volume of air in the cabin, which makes it less insulated from heat. 

However, it should be noted that the SUV started off with a higher interior air temperature due to it being exposed 

to direct sunlight in the morning. Addtionally, for all the conditions, it was observed that after exactly 4:00PM the 

interior air temperature showed a sharp decrease on temperature. This may suggest that the sunlight intensity 

decreases around this time. After observing the cars under all the different conditions, it is very clear that as long as 

there is presence of sunlight, the interior air temperature of the car increases well past the thermal comfort level 

(28ºC) for humans. In our next research, we are developing a mitigation technology for this problem. 

 

ACKNOWLEDGEMENT 

We would like to thanks Universiti Teknologi Brunei for financial support through final year project. 

 

REFERENCES 

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2. M. Mansor et al. (2014). Variation of Car Cabin Temperature Influenced by Ventilation under Direct Sun 

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3. R. Manning and J. Ewing (2009). Temperature of Cars Study. February 2009. [Accessed: 04-May-2018]. 

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8. C. McLaren et al. (2005). Heat Stress from Enclosed Vehicles: Moderate Ambient Temperatures Cause Significant 

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9. Grundstein et al. (2009). Maximum vehicle cabin temperatures under different meteorological conditions. 

International Journal of Biometeorology, 53(3), 255-261. 

  

Interior Air Temperature 

Ambient Temperature