ISSN: 2180-1053        Vol. 3     No. 2    July-December 2011

Development of a Stand-alone Solar Powered Bus Stop 

55

Development of a StanD-alone Solar 
powereD BuS Stop 

mohd afzanizam mohd rosli1, mohd Zaid akop 2, muhd ridzuan 
mansor3, Sivarao S.4

1,2,3Faculty of Mechanical Engineering, Universiti Teknikal Malaysia Melaka, 
76100 Durian Tunggal, Melaka.

4Faculty of Manufacturing Engineering, Universiti Teknikal Malaysia 
Melaka, 76100 Durian Tunggal, Melaka.

Email: 1afzanizam@utem.edu.my

ABSTRACT

This paper presents the development of a stand-alone solar photovoltaic 
(PV) system for bus stop at Universiti Teknikal Malaysia Melaka, 
Malaysia. The design intent for the bus stop was to provide lighting 
and information to the bus stop users using reliable renewable energy 
system as well as to promote green technology awareness to the university 
residences. The stand-alone PV system was designed to power two units of 
CFL lamps and an LED display unit installed at the bus stop. Five units 
of polycrystalline photovoltaic modules with 110W rating each and four 
deep cycle battery units were utilized to provide three days of autonomy 
period for system operation. A part from that, 15 degree of tilt angle was 
selected for PV module placement to provide optimum energy generation 
as well as self cleaning for the modules. After the bus stop structure 
construction, the PV system was installed and commissioned. Final results 
from the commissioning process showed that the system is able to operate 
successfully as per design requirement. 

KEYWORDS: Solar photovoltaic, Bus stop, Stand-alone system

Development of a Stand-alone Solar Powered Bus Stop 
 

Mohd Afzanizam Mohd Rosli1, Mohd Zaid Akop 2, Muhd Ridzuan Mansor3, Sivarao S.4 
 

1,2,3Faculty of Mechanical Engineering, Universiti Teknikal Malaysia Melaka, 76100 Durian 
Tunggal, Melaka. 

4Faculty of Manufacturing Engineering, Universiti Teknikal Malaysia Melaka, 76100 Durian 
Tunggal, Melaka. 

 
Email: 1afzanizam@utem.edu.my 

 
ABSTRACT 

 
This paper presents the development of a stand-alone solar photovoltaic (PV) system for bus stop at 
Universiti Teknikal Malaysia Melaka, Malaysia. The design intent for the bus stop was to provide 
lighting and information to the bus stop users using reliable renewable energy system as well as to 
promote green technology awareness to the university residences. The stand-alone PV system was 
designed to power two units of CFL lamps and an LED display unit installed at the bus stop. Five 
units of polycrystalline photovoltaic modules with 110W rating each and four deep cycle battery 
units were utilized to provide three days of autonomy period for system operation. A part from that, 
15 degree of tilt angle was selected for PV module placement to provide optimum energy 
generation as well as self cleaning for the modules. After the bus stop structure construction, the PV 
system was installed and commissioned. Final results from the commissioning process showed that 
the system is able to operate successfully as per design requirement.  
 
KEYWORDS: Solar photovoltaic, Bus stop, Stand-alone system 
 
 
1.0 INTRODUCTION 
 
Photovoltaic or PV is currently one of the most attractive options for renewable energy 
resources in the world. Malaysia which is blessed with yearly average solar irradiance of 
1400 to 1900 kWh/m2 is considered to be in a very advantageous position to harness the 
unlimited energy towards PV applications to cater current domestic energy demand 
(Malaysian PV Handbook, 2009). The technology offers free and renewable energy, no 
emission effects during energy production, help to reduce dependency to conventional 
power supply, as well as easy to install and maintain due to its modular characteristics 
(Chow, 2010). 

 
Up to date, solar photovoltaic (PV) system application is divided into two distinctive 
categories, which are grid-connected system and stand-alone or off-grid system. The grid 
connected PV system operates by linking the solar PV with the utility-grid connection, 
where as the stand alone PV system operates without connection to the utility grid and 
utilize a battery system to store the excess energy generated by the solar PV as well as 
supplying the needed energy when no power from the sun is available. Both system are 
widely applied especially in Malaysia, however the stand-alone system offer notable 



ISSN: 2180-1053        Vol. 3     No. 2    July-December 2011

Journal of Mechanical Engineering and Technology 

56

advantage of able to operate in remote areas where utility-grid connection are not viable 
(Zekai, 2008). 

 
In this project, an innovative design of bus stops is proposed where the infrastructure is to 
be equips with lamps and electrical signboard powered by solar PV energy system. The new 
system is aimed to provide higher level human comfort as well as information to user, and 
the prototype is targeted to be applied in Main Kampus, Universiti Teknikal Malaysia 
Melaka. Currently, bus stops in UTeM is designed without any equipment to provide proper 
notice board and LED display to give better information for the public. This paper described 
the overall design and development process for the UTeM solar powered bus stop such as 
PV system sizing, structure design and development as well as PV system installation and 
commissioning. 

 
 
2.0 METHODOLOGY 
 
The overall research methodology implement in this project is shown in Fgure 1 below. 

 

Development of a Stand-alone Solar Powered Bus Stop 
 

Mohd Afzanizam Mohd Rosli1, Mohd Zaid Akop 2, Muhd Ridzuan Mansor3, Sivarao S.4 
 

1,2,3Faculty of Mechanical Engineering, Universiti Teknikal Malaysia Melaka, 76100 Durian 
Tunggal, Melaka. 

4Faculty of Manufacturing Engineering, Universiti Teknikal Malaysia Melaka, 76100 Durian 
Tunggal, Melaka. 

 
Email: 1afzanizam@utem.edu.my 

 
ABSTRACT 

 
This paper presents the development of a stand-alone solar photovoltaic (PV) system for bus stop at 
Universiti Teknikal Malaysia Melaka, Malaysia. The design intent for the bus stop was to provide 
lighting and information to the bus stop users using reliable renewable energy system as well as to 
promote green technology awareness to the university residences. The stand-alone PV system was 
designed to power two units of CFL lamps and an LED display unit installed at the bus stop. Five 
units of polycrystalline photovoltaic modules with 110W rating each and four deep cycle battery 
units were utilized to provide three days of autonomy period for system operation. A part from that, 
15 degree of tilt angle was selected for PV module placement to provide optimum energy 
generation as well as self cleaning for the modules. After the bus stop structure construction, the PV 
system was installed and commissioned. Final results from the commissioning process showed that 
the system is able to operate successfully as per design requirement.  
 
KEYWORDS: Solar photovoltaic, Bus stop, Stand-alone system 
 
 
1.0 INTRODUCTION 
 
Photovoltaic or PV is currently one of the most attractive options for renewable energy 
resources in the world. Malaysia which is blessed with yearly average solar irradiance of 
1400 to 1900 kWh/m2 is considered to be in a very advantageous position to harness the 
unlimited energy towards PV applications to cater current domestic energy demand 
(Malaysian PV Handbook, 2009). The technology offers free and renewable energy, no 
emission effects during energy production, help to reduce dependency to conventional 
power supply, as well as easy to install and maintain due to its modular characteristics 
(Chow, 2010). 

 
Up to date, solar photovoltaic (PV) system application is divided into two distinctive 
categories, which are grid-connected system and stand-alone or off-grid system. The grid 
connected PV system operates by linking the solar PV with the utility-grid connection, 
where as the stand alone PV system operates without connection to the utility grid and 
utilize a battery system to store the excess energy generated by the solar PV as well as 
supplying the needed energy when no power from the sun is available. Both system are 
widely applied especially in Malaysia, however the stand-alone system offer notable 



ISSN: 2180-1053        Vol. 3     No. 2    July-December 2011

Development of a Stand-alone Solar Powered Bus Stop 

57

 
 

FIGURE 1 
Overall Research Flow Chart 

 
Among the important stage in this project was the system development where the sizing of 
the PV standalone system is conducted. In order to attain an optimum design for the system, 
several sizing criteria such as location selection, design specification, determination of PV 
modules and battery capacity etc. were carefully calculated based on MS1837:2005 PV 
standard requirements (Malaysian Standard, 2005). The structure was later designed to 
accommodate the system sizing results using Solidworks CAD software. System testing and 
commissioning were performed in the final stage of the project to ensure that the PV system 
able to operate as per requirement.    
 
 
3.0 SYSTEM SIZING 
 

Not good 

Good 

Start 

Project planning  

Evaluation 

System Installations 

Modify 

System Testing 

Performance 
Monitoring 

End 

System Development 

Evaluation 

Literature Review on Current Design of Solar 
System 

Not good 

Good 

Modify 

FIGURE 1 Overall Research Flow Chart



ISSN: 2180-1053        Vol. 3     No. 2    July-December 2011

Journal of Mechanical Engineering and Technology 

58

3.1 Selection of Bus Stop Location 
 
The first approach in designing the UTeM solar bus stop was to choose the suitable location 
for the structure. This is very crucial in order to ensure that the solar modules installed later 
on will have exposed to adequate sunray throughout the entire day for maximum power 
generation.  The surrounding of the bus stop location was also ensured to be clear from 
shading sources such as tress and nearby structure especially to the solar modules. The bus 
stop must also be easily accessible to the users to serve its main function. The proposed 
location of the UTeM solar bus stop is shown in Figure 2 below. 

 

 
 

FIGURE 2 
UTeM Solar Bus Stop Location 

 
3.2 Load Determination 
 
The details of the electrical appliances designed for the bus stop and its power rating is 
shown in Table 1 below. Based on Table 1, the majority of the loads selected operated on 
AC current. This is mainly because of low cost of acquiring the component compared to DC 
current components. A part from that, the system load is also divided into two cases which 
are with and without spare loads. The spare loads are incorporated into the design to cater 
for unexpected higher power usage in the future. The total load per hours in the case of 
without spare load is 953 Watt-hours daily and in the case of spare loads is 1269 Watt-hours 
daily. 
 
 

TABLE 1 
Load profile for UTeM solar bus stop in a day 

 

No Load Detail Type Quantity 
Power/Unit 

(W) 
Operating 

Time 
Operating 
hour/Day 

Total 
Power 
(Wh) 

1 CFL Lamp AC 2 18 7pm – 1am 6 216 
2 LED AC 1 49 8am – 14 686 

Display 10pm 

3 Internal System 
DC & 

AC 1 8.5 - 6 51 

4 *13A socket AC 1 100 - 1 100 

5 *Spare loads AC 2 18 - 6 216 

 
 
3.3 System Specification and Tilt Angle 
 
Several parameters have been determined for the design specification of the solar bus stop. 
First and foremost, the new UTeM solar bus stop is set to operate as a standalone system, 
where the power source is generated through PV modules only. The system is also set to be 
operated using 12V system voltage and must be able to operate up to 3 days of autonomy (in 
the case where zero sunlight occurred). The estimated achievable maximum solar radiation 
per day for the system is set to 3 peak sun hours and because the bus stop is a standalone 
photovoltaic system, the maximum depth of discharge for the battery used is the system is 
set to 80% capacity. The solar module is set to be placed on top of the bus stop roof to avoid 
any shading and to optimize the bus stop area. Hence, another important parameter that was 
determined was the tilt angle for the solar module installation. The location for the bus stop 
is roughly at the latitude 2°18'51.61"N and longitude 102°19'8.17"E, where, optimum tilt 
angle for the solar module is from 2° to 3° facing south. However, it is recommended that 
for sites at latitudes between 15°S and 15°N, a tilt angle of 15° is used. Hence, the tilt angle 
selected for the bus stop design is 15° to enable optimum energy generation as well as self 
cleaning for the modules. Based on solar irradiation data for Malaysia, the approximate 
average solar irradiance for the given latitude is 1400 W/m2 (Sulaiman et al., 2008). 
 
3.4 Battery and Module Sizing 
 
Based on load data in Table 1 and design specifications, the sizing of the battery unit and 
the solar PV modules were performed. The determination for the number of batteries and 
PV modules were carefully conducted to ensure optimum sizing of the system can be 
achieved, which will benefits in lowering down the overall system cost as well as ensuring 
the system is able to operate efficiently. The sizing approach for standalone system is more 
delicate because the system operates solely on solar energy and energy from the batteries, 
compared with grid connected system. The battery must be able to supply the required 
power for minimum 3 days autonomy while the PV modules must be able to supply the 
power during sunlight as well as charging the battery to its maximum capacity continuously. 
Table 2 below shows the final result for the battery and PV module sizing. 
 
 
 
 

 

 
 

FIGURE 1 
Overall Research Flow Chart 

 
Among the important stage in this project was the system development where the sizing of 
the PV standalone system is conducted. In order to attain an optimum design for the system, 
several sizing criteria such as location selection, design specification, determination of PV 
modules and battery capacity etc. were carefully calculated based on MS1837:2005 PV 
standard requirements (Malaysian Standard, 2005). The structure was later designed to 
accommodate the system sizing results using Solidworks CAD software. System testing and 
commissioning were performed in the final stage of the project to ensure that the PV system 
able to operate as per requirement.    
 
 
3.0 SYSTEM SIZING 
 

Not good 

Good 

Start 

Project planning  

Evaluation 

System Installations 

Modify 

System Testing 

Performance 
Monitoring 

End 

System Development 

Evaluation 

Literature Review on Current Design of Solar 
System 

Not good 

Good 

Modify 

3.1 Selection of Bus Stop Location 
 
The first approach in designing the UTeM solar bus stop was to choose the suitable location 
for the structure. This is very crucial in order to ensure that the solar modules installed later 
on will have exposed to adequate sunray throughout the entire day for maximum power 
generation.  The surrounding of the bus stop location was also ensured to be clear from 
shading sources such as tress and nearby structure especially to the solar modules. The bus 
stop must also be easily accessible to the users to serve its main function. The proposed 
location of the UTeM solar bus stop is shown in Figure 2 below. 

 

 
 

FIGURE 2 
UTeM Solar Bus Stop Location 

 
3.2 Load Determination 
 
The details of the electrical appliances designed for the bus stop and its power rating is 
shown in Table 1 below. Based on Table 1, the majority of the loads selected operated on 
AC current. This is mainly because of low cost of acquiring the component compared to DC 
current components. A part from that, the system load is also divided into two cases which 
are with and without spare loads. The spare loads are incorporated into the design to cater 
for unexpected higher power usage in the future. The total load per hours in the case of 
without spare load is 953 Watt-hours daily and in the case of spare loads is 1269 Watt-hours 
daily. 
 
 

TABLE 1 
Load profile for UTeM solar bus stop in a day 

 

No Load Detail Type Quantity 
Power/Unit 

(W) 
Operating 

Time 
Operating 
hour/Day 

Total 
Power 
(Wh) 

1 CFL Lamp AC 2 18 7pm – 1am 6 216 
2 LED AC 1 49 8am – 14 686 

FIGURE 2 UTeM Solar Bus Stop Location

TABLE 1 Load profile for UTeM solar bus stop in a day



ISSN: 2180-1053        Vol. 3     No. 2    July-December 2011

Development of a Stand-alone Solar Powered Bus Stop 

59

Display 10pm 

3 Internal System 
DC & 

AC 1 8.5 - 6 51 

4 *13A socket AC 1 100 - 1 100 

5 *Spare loads AC 2 18 - 6 216 

 
 
3.3 System Specification and Tilt Angle 
 
Several parameters have been determined for the design specification of the solar bus stop. 
First and foremost, the new UTeM solar bus stop is set to operate as a standalone system, 
where the power source is generated through PV modules only. The system is also set to be 
operated using 12V system voltage and must be able to operate up to 3 days of autonomy (in 
the case where zero sunlight occurred). The estimated achievable maximum solar radiation 
per day for the system is set to 3 peak sun hours and because the bus stop is a standalone 
photovoltaic system, the maximum depth of discharge for the battery used is the system is 
set to 80% capacity. The solar module is set to be placed on top of the bus stop roof to avoid 
any shading and to optimize the bus stop area. Hence, another important parameter that was 
determined was the tilt angle for the solar module installation. The location for the bus stop 
is roughly at the latitude 2°18'51.61"N and longitude 102°19'8.17"E, where, optimum tilt 
angle for the solar module is from 2° to 3° facing south. However, it is recommended that 
for sites at latitudes between 15°S and 15°N, a tilt angle of 15° is used. Hence, the tilt angle 
selected for the bus stop design is 15° to enable optimum energy generation as well as self 
cleaning for the modules. Based on solar irradiation data for Malaysia, the approximate 
average solar irradiance for the given latitude is 1400 W/m2 (Sulaiman et al., 2008). 
 
3.4 Battery and Module Sizing 
 
Based on load data in Table 1 and design specifications, the sizing of the battery unit and 
the solar PV modules were performed. The determination for the number of batteries and 
PV modules were carefully conducted to ensure optimum sizing of the system can be 
achieved, which will benefits in lowering down the overall system cost as well as ensuring 
the system is able to operate efficiently. The sizing approach for standalone system is more 
delicate because the system operates solely on solar energy and energy from the batteries, 
compared with grid connected system. The battery must be able to supply the required 
power for minimum 3 days autonomy while the PV modules must be able to supply the 
power during sunlight as well as charging the battery to its maximum capacity continuously. 
Table 2 below shows the final result for the battery and PV module sizing. 
 
 
 
 

 



ISSN: 2180-1053        Vol. 3     No. 2    July-December 2011

Journal of Mechanical Engineering and Technology 

60

TABLE 2 
Sizing for Battery and PV Modules 

 
Sizing Details Value 

A. Battery  
 i.  Amp-hour required excluding spare load (Ah) 297.8 
 ii.  Amp-hour required including spare load (Ah) 396.6 
 iii.  No of battery need 4 
B. PV Module  
 i. Maximum power, Pm (W) 110 
 ii. Maximum voltage, Vm (V) 17.2 
 iii. Maximum current, Im (A) 6.4 
 iv. Short-circuit voltage, Voc (V) 21.7 
 v. Short-circuit current, Isc (A) 6.9 
 vi Total module required excluding spare loads 4 
 vii. Total module required including spare loads 5 
 viii. Array configuration 5 x 1 

 
 
3.5 Balance-of-system (BOS) Sizing 
 
The final procedure for the sizing is to determine the specification for charge controller and 
inverter. The charge controller is used to regulate the power from the PV modules to the 
loads and vice versa efficiently. The inverter in the other hand is selected to convert the DC 
voltage produced from the PV modules to AC voltage needed for the load operations (CFL 
lamps, LED display etc.). The results of the balance of system sizing are shown in Table 3 
below. 
 

TABLE 3 
Balance-of-system (BOS) for UTeM Solar Bus Stop 

 
BOS Sizing Details Value 

A. Charge Controller  
 i.  System voltage : minimum/maximum (V) 12/24 
 ii.  Total rated solar current (A) 18.5 
 iii. Total maximum array current (A) 26.5 
 iv. Total rated load current (A) 7.8 
 v. Total maximum load current (A) 19.2 
B. Inverter  
 i. AC system voltage (V) 240 
 ii. AC system frequency (Hz) 50 
 iii. Power factor (cos(pi)) 0.85 
 iv. Rated VA based on excluding spare loads 110 
 v. Rated VA based on including spare loads 270 

 
 

TABLE 1 Sizing for Battery and PV Modules

TABLE 3 Balance-of-system (BOS) for UTeM Solar Bus Stop



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Development of a Stand-alone Solar Powered Bus Stop 

61

A part from that, another important parameter for the BOS is the appropriate selection of 
cable size to minimize the power transmission lost in the cables. Due to the small amount of 
energy generated by the PV modules, thus the sizing process in this project was also focused 
to reduce any losses that may be created in the system which can deteriorate the system 
performance. The diameter of cable size selected is 4mm for running from the charge 
controller to the loads as well as from the batteries to the charge controller and 6mm cable 
diameter for cable designed from the PV modules to the charge controller. The selected 
cable sizes for the whole system were carefully calculated to permit maximum cabling 
losses of 4% based on requirement stated in the Malaysian Standard (Malaysian Standard, 
2005). 
 
3.6 Results of System Sizing 
 
Based on the system sizing, the appropriate components for the UTeM solar bus stop system 
were selected. The design specific yield of the system is 1037.1 kWh/kWp.  The installation 
quality of the designed bus stop measured in term of performance ratio was found to be 
approximately 74% which satisfy the MS1837:2005 PV standard requirements (Malaysian 
Standard, 2005). A timer was also incorporated in the system to control precisely the 
operation hours of the loads in the system. Table 4 and Figure 3 below show the description 
of the selected equipments for the standalone PV system and the system overall schematic 
diagram. 
 

TABLE 4 
Equipments for UTeM solar bus stop 

 
No Item Quantity Desciptions 
1 Solar Module 5 110 W, 12V, Polycrystalline. Brand: SolarTif 
2 Battery 4 100 Ah, 12V, JXH100-12 Valve Regulated Lead 

Acid. Brand: MPower 
3 Charge Controller 1 Model PL40, 12-48V, 30A. Brand: Phocos 
4 Inverter 1 Standalone Sinewave Inverter, Model 

Picollo.Brand: ASP 
 

TABLE 4  Equipments for UTeM solar bus stop



ISSN: 2180-1053        Vol. 3     No. 2    July-December 2011

Journal of Mechanical Engineering and Technology 

62

 
FIGURE 3 

Schematic Diagram of the UTeM Solar Bus Stop 
 
 

4.0 BUS STOP DESIGN AND CONSTRUCTION 
 
The design intent is for the bus stop to provide lighting and visual display to the users of the 
bus stop. A part from that, the bus stop structure must also be able to accommodate the solar 
modules as well as the rest of the balance of system components. Acknowledging the above 
requirements, a design for the UTeM bus stop was proposed and shown in Figure 4 below. 
 

 
 

FIGURE 4 
UTeM Solar Bus Stop Design 

 
The UTeM bus stop structure encompassed several features. The roof of the structure is 
tilted at 15 degree from horizontal plane to enable tilt angle of 15 degree for the module 
installation. The bus stop foundation is needed to be flat to ensure the tilt angle for the 
modules can be achieved. The roof structure also houses the CFL lamps and LED display 
unit. Due to the location of the LED display unit where it is placed on the front of the bus 
stop roof facing the main road, the display is required to be fabricated based on IP65 casing 
requirement for ensuring reliable outdoor performance. The overall structure of the bus stop 
will be made from concrete as well as for the base of the bus stop. The balance-of-system 
components are located separately in a special housing behind the bus stop structure for ease 
of maintenance and security control. Figure 5 below show the UTeM bus stop in the end of 
the construction process. 

 
 

 
 

 
FIGURE 3 

Schematic Diagram of the UTeM Solar Bus Stop 
 
 

4.0 BUS STOP DESIGN AND CONSTRUCTION 
 
The design intent is for the bus stop to provide lighting and visual display to the users of the 
bus stop. A part from that, the bus stop structure must also be able to accommodate the solar 
modules as well as the rest of the balance of system components. Acknowledging the above 
requirements, a design for the UTeM bus stop was proposed and shown in Figure 4 below. 
 

FIGURE 3 Schematic Diagram of the UTeM Solar Bus Stop

FIGURE 4 UTeM Solar Bus Stop Design



ISSN: 2180-1053        Vol. 3     No. 2    July-December 2011

Development of a Stand-alone Solar Powered Bus Stop 

63

 
 

FIGURE 4 
UTeM Solar Bus Stop Design 

 
The UTeM bus stop structure encompassed several features. The roof of the structure is 
tilted at 15 degree from horizontal plane to enable tilt angle of 15 degree for the module 
installation. The bus stop foundation is needed to be flat to ensure the tilt angle for the 
modules can be achieved. The roof structure also houses the CFL lamps and LED display 
unit. Due to the location of the LED display unit where it is placed on the front of the bus 
stop roof facing the main road, the display is required to be fabricated based on IP65 casing 
requirement for ensuring reliable outdoor performance. The overall structure of the bus stop 
will be made from concrete as well as for the base of the bus stop. The balance-of-system 
components are located separately in a special housing behind the bus stop structure for ease 
of maintenance and security control. Figure 5 below show the UTeM bus stop in the end of 
the construction process. 

 
 

 
 

 
 

FIGURE 5 
UTeM Bus Stop after Construction 

 
 
 
5.0 SYSTEM INSTALLATION AND COMMISSIONING 
 
After the bus stop structure was constructed, the stand-alone PV system was later installed 
at the location. Simple L-shape brackets were first placed on top of the structure roof acting 
as the mounting points for the PV modules. Five units of PV modules were installed in 5x1 
array configuration as per sizing requirement at 15 degree tilt angle. Later, the CFL lights 
and LED display unit were installed on the bus stop. The batteries and balance-of-system 
components were installed separately on a special housing behind the bus stop. Wires 
connecting the modules, loads and the rest of the PV system are secured inside conduits to 
ensure safety to the users as well as to protect from surrounding effect such as rain water 
that may cause it to deteriorate prematurely. The wires connecting the modules and the 
balance-of-system housing is also burried in ground for safety purposes. The installed PV 
system on the bus stop and the PV balance of system are shown in Figure 6 and Figure 7 
below. 
 

 
 
 
 
 
 
 
 

 
 

FIGURE 5 
UTeM Bus Stop after Construction 

 
 
 
5.0 SYSTEM INSTALLATION AND COMMISSIONING 
 
After the bus stop structure was constructed, the stand-alone PV system was later installed 
at the location. Simple L-shape brackets were first placed on top of the structure roof acting 
as the mounting points for the PV modules. Five units of PV modules were installed in 5x1 
array configuration as per sizing requirement at 15 degree tilt angle. Later, the CFL lights 
and LED display unit were installed on the bus stop. The batteries and balance-of-system 
components were installed separately on a special housing behind the bus stop. Wires 
connecting the modules, loads and the rest of the PV system are secured inside conduits to 
ensure safety to the users as well as to protect from surrounding effect such as rain water 
that may cause it to deteriorate prematurely. The wires connecting the modules and the 
balance-of-system housing is also burried in ground for safety purposes. The installed PV 
system on the bus stop and the PV balance of system are shown in Figure 6 and Figure 7 
below. 
 

 
 
 
 
 
 
 
 

FIGURE 5 UTeM Bus Stop after Construction



ISSN: 2180-1053        Vol. 3     No. 2    July-December 2011

Journal of Mechanical Engineering and Technology 

64

 
 
 
 

 
 
 

FIGURE 6 
UTeM Bus Stop with Stand-alone PV System 

 

 
 

FIGURE 5 
UTeM Bus Stop after Construction 

 
 
 
5.0 SYSTEM INSTALLATION AND COMMISSIONING 
 
After the bus stop structure was constructed, the stand-alone PV system was later installed 
at the location. Simple L-shape brackets were first placed on top of the structure roof acting 
as the mounting points for the PV modules. Five units of PV modules were installed in 5x1 
array configuration as per sizing requirement at 15 degree tilt angle. Later, the CFL lights 
and LED display unit were installed on the bus stop. The batteries and balance-of-system 
components were installed separately on a special housing behind the bus stop. Wires 
connecting the modules, loads and the rest of the PV system are secured inside conduits to 
ensure safety to the users as well as to protect from surrounding effect such as rain water 
that may cause it to deteriorate prematurely. The wires connecting the modules and the 
balance-of-system housing is also burried in ground for safety purposes. The installed PV 
system on the bus stop and the PV balance of system are shown in Figure 6 and Figure 7 
below. 
 

 
 
 
 
 
 
 
 

FIGURE 6 UTeM Stop with Stand-alone PV System



ISSN: 2180-1053        Vol. 3     No. 2    July-December 2011

Development of a Stand-alone Solar Powered Bus Stop 

65

 
 

FIGURE 7 
Housing for Batteries and Balance-of-system Components 

 
 
6.0 CONCLUSION 
 
In conclusion, the standalone solar PV system for UTeM green bus stop was successfully 
developed in this project. The solar PV system comprised of five polycrystalline modules in 
5x1 array configuration and four deep cycle batteries which give power to two units of CFL 
lamps and a LED display unit. The bus stop structure was design and constructed to 
accommodate the module tilt angle of 15 degree. Results from the testing and 
commissioning process performed show that the solar PV system was able to perform as per 
design requirement. The solar powered bus stop developed in this project was proven not 
only to perform as conventional bus stop, but also able to  provide human comfort and 
information to the users as well as promoting green technology within the university and its 
residence. 
 
 
7.0 ACKNOWLEDGEMENT 
 
The authors would like to thank Universiti Teknikal Malaysia Melaka for providing the 
support and fund for accomplishment of this project. The project was funded under UTeM 
top-down research grant PJP/2010/FKM(15A)-S715. 
 
 

FIGURE 7 Housing for Batteries and Balance-of-system Components



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Journal of Mechanical Engineering and Technology 

66

8.0 REFERENCES 
 
 

PV Industry Handbook. 2009. Pusat Tenaga Malaysia. Malaysia. 
T.T. Chow. 2010. A Review on Photovoltaic/thermal Hybrid Solar Technology, Journal of Applied 

Energy, Vol. 87, pp. 365-379. 
S. Zekai. 2008. Solar Energy Fundamental and Modeling Technique: Atmosphere, Environment, 

Climate Change and Renewable Energy. 1st Ed. Ginora, Spain: Springer 
Installation of Grid Connected Photovoltaic (PV) System, Malaysian Standard MS1837:2005, 

SIRIM, Malaysia. 
Sulaiman S., Kamaruzzaman S., and Ahmad M.O. 2008. Solar Irradiation Handbook for 

Photovoltaic Systems Design in Malaysia. Solar Energy Research Institute, Universiti 
Kebangsaan Malaysia, Malaysia. ISBN: 9789675048326. 

 


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