TX_1~AT/TX_2~AT


International Journal of Energy Economics and 
Policy

ISSN: 2146-4553

available at http: www.econjournals.com

International Journal of Energy Economics and Policy, 2022, 12(1), 401-406.

International Journal of Energy Economics and Policy | Vol 12 • Issue 1 • 2022 401

The Optimization Using Electric Ground Support Equipment in 
Aviation Industry

Mustika Sari1,2*, Wan Mazlina Wan Mohamed1, Siti Ayu Jalil1

1Malaysia Institute of Transport, Universiti Teknologi MARA, Malaysia 40450 Shah Alam, Selangor Darul Ehsan, Malaysia, 
2Institute Transportation and Logistic Trisakti, Jakarta, Indonesia. *Email: mustika0017@gmail.com

Received: 13 August 2021 Accepted: 22 December 2021 DOI: https://doi.org/10.32479/ijeep.11711

ABSTRACT

An airport is one of the country’s infrastructures that provides air transportation services. In providing its services, to ensure aircraft safety, airports must 
conform to a set of international technical operating standards and planned operating procedures. In addition, airports also have a social responsibility to 
prevent pollution and support eco green. Therefore, this study aims to conduct a benefit cost analysis using electric ground support equipment in aviation 
industry, both for using e-GSE using diesel and using e-GSE using electricity. The method used in this research is the Benefit Cost Ratio method. Based 
on the research results, it shows that the use of e-GSE using both diesel and electricity is feasible because it has an net present value (NPV) value of more 
than 0. However, when compared with the assumption of 25 years of use, the use of e-GSE using diesel is considered more profitable than using electricity.

Keywords: Benefit Cost Analysis, Electric Ground Support Equipment 
JEL Classifications: P41, P28, P43

1. INTRODUCTION

Airport operators are responsible for expanding their facilities and 
services in order to play a role in the aviation industry. Among the 
responsibilities are terminal services, ground services facilities, and 
passenger baggage and cargo movement between the airfield and 
terminals. Airport operators are also in responsible to manage the 
airport’s commercial facilities, ground transportation from and to the 
airport, parking infrastructure, surface access links, and other related 
factors outside the confines of an airport terminal (Graham, 2018).

Airports are the source of emissions that have a negative impact 
on the environment, and these emissions are produced by activities 
both inside and outside the airport. As a result, living near airports 
may pose a significant risk to people’s health. Airport operators 
are becoming more aware of how the construction, operation, 
maintenance, and other activities at airport facilities can contribute 
to the industry’s overall impacts on climate change (Giuffre and 
Grana, 2011).

Ground handling is a service provided by airlines that assists in the 
crusade of aircraft while on land by using a few tools to measure in 
motorized and non-motorized modes for the purposes of accuracy, 
safety, security, and cost-effectiveness. Ground handling costs 
a lot of money to complete work for the necessary operational 
coordination with all parties involved with the movement of 
tools for land. Such tools would require diesel fuel, which has 
been used by all ground handling vehicles, referred to as ground 
support equipment (GSE). Ground handling, which is frequently 
associated with the operation of ground support equipment in 
airports, plays a role in emission reduction efforts. Efforts are 
currently being made by ground handling companies to plan for 
and gradually implement electric vehicles or renewable fuels 
(Aerospace, 2012).

The total scope of ground handling work includes nine standard 
service units: passenger handling, baggage handling, cargo 
and mail handling, aircraft handling and loading, load control, 
air side management and safety, aircraft movement control, 

This Journal is licensed under a Creative Commons Attribution 4.0 International License



Sari, et al.: The Optimization Using Electric Ground Support Equipment in Aviation Industry

International Journal of Energy Economics and Policy | Vol 12 • Issue 1 • 2022402

standard ground handling agreement, and airport handling. GSE 
requirements (International Air Transport Association, 2014).

GSE research has yet to be as extensive as that of aircraft 
operations, fleets, and emissions. GSE’s current data is regarded 
as untrustworthy, limited, and out of date. In order to adequately 
plan and maintain the increasing demands for excellent air quality 
service, the FAA requires accurate GSE data. Air quality can only 
be improved if airports implement effective strategies to reduce 
surface emissions (Airport Cooporative Research Program, 
2012a).

The airside ground operation contributes significantly to 
emissions. Taxiing is one of the most emission-intensive modes 
of transportation during departure (Bubalo et al., 2017). The 
emission can dangered the human health (Jaafar et al., 2018), 
such as increase vascular dementia (Li et al., 2019), degradation 
of lung function and many health problem (Suhaimi et al., 2020)

The level of polluted engine exhaust emissions, unsafe air pollution 
(HAPs), and greenhouse gases (GHGs) in every piece of GSE 
(with the exception of electric GSE) is heavily dependent on the 
engine size, which is typically measured in brake horsepower 
(BHP), the type of fuel (diesel or gasoline), the engine’s on and 
run time, and load factors. The load factors are defined as the 
average energy demand ratio on the equipment required to reach 
the maximum (peak load) of the equipment (Airport Cooporative 
Research Program, 2012b). The air pollution mainly come form 
vehicles, and the concertation of NO and CO reduce significantly 
during COVID-19 pandemic, when less vehicles are on the road 
(Talib et al., 2021).

The use of eco fuels by air transport companies is one of 
the Indonesian government’s efforts to reduce air pollution. 
Government regulations must provide for the provision and use of 
eco fuels to support renewable energy, as required by Government 
Regulation No. 26, 2008. The usage of gas as energy source can 
reduce the carbon emission (Farabi et al., 2019). Enforcement is 
also aimed at assisting air transport for aircraft on the ground, 
also known as ground handling. The government also should have 
roadmap on future energy, either renewable or non-renewable 
energy, such as the use of wind and water energy, biomass, 
biodiesel, biogas, and other sources (Faizah and Husaeni, 2018).

Reduced carbon emissions from air transportation and airport 
operations have been included in Indonesia’s Action Plans through 
the implementation of renewable energy for airport facilities and 
the ongoing implementation of eco-airport programs. As a result, 
in 2017, DGCA Indonesia issued a DG Decree establishing 
an emissions reduction program for airport operations. The 
incorporation of the degree requires airports in Indonesia to report 
to the Director General on a regular basis their carbon emissions, 
including both emissions production and reduction. The decree 
is aimed at measuring the effectiveness of eco-airport program 
implementation and monitoring the emissions reduction progress 
as stipulated in Indonesian State Action Plans (Indonesia Team, 
2018).

Furthermore, the APEC annual meeting stated that the Indonesian 
government has committed to mitigating climate change and 
reducing greenhouse gas emissions. Presidential Decree 71/2011 
on the implementation of the greenhouse gas inventory, and 
the energy and transportation sectors contribute 0.056 percent 
(Samad, 2013). While a green eco vehicle costs slightly more 
than a conventional car, the return on investment is immediate. 
Fuel, insurance, and maintenance costs are drastically reduced, 
saving a significant amount of money in the long run. Proper care 
and responsible driving are required when operating any type of 
vehicle, and eco vehicles are designed to have a minimal impact 
on the engine (Kuttner, 2015).

While a green eco vehicle costs slightly more than a conventional 
car, the return on investment is immediate. Fuel, insurance, and 
maintenance costs are drastically reduced, saving a significant 
amount of money in the long run. Proper care and responsible 
driving are required when operating any type of vehicle, and eco 
vehicles are designed to have a minimal impact on the engine.

2. METHODOLOGY

This study makes use of secondary data from a third party, 
specifically data from a ground handling company and an aviation 
ground support equipment company. The information includes the 
cost of electrical GSE, diesel GSE, and operation. Cost Benefit 
Analyst in this research is applied to transportation investments, 
project scenario assumptions should be aware that these frequently 
have infinite lifetimes. Energy 25 years, Water and Environment 
30 years, Railways 30 years, Roads 25 years, Ports and Airports 
25 years, Telecommunications 15 years, Industry 10 years, Other 
Services 15 years are typical project lifetimes for public investment 
projects (Jones et al., 2014).

This research using Nett Present Value (NPV). NPV is the 
difference between the value of incoming cash flows and the 
value of cash outflows over a period of time. The feasibility can 
implement if the NPV value is greater than zero.

The formula to calculate is:

( )
0

 
(1 )

n
t

t
t

Benefit Cost
NPV

r=

−
=

+∑

Where:
r = discount rate
t = year
n = analytic horizon (in year).

3. RESULT AND DISCUSSION

Cost benefit analysis (CBA) has been widely accustomed support 
the decision-making process in transport. The consideration of 
non-economic variables into the analysis, such as noise, accidents, 
air pollution and so on, has been troublesome for the application 
of CBA (Tudela et al., 2006).



Sari, et al.: The Optimization Using Electric Ground Support Equipment in Aviation Industry

International Journal of Energy Economics and Policy | Vol 12 • Issue 1 • 2022 403

CBA is a formal process for evaluating a project that evolved 
from the economic constructs of consumer surplus and 
externality. It then moved into a formal regulated process 
based upon work by economists and government agencies and 
is now required by many entities for project approval, seeking 
the efficient allocation of resources. It is a decision making tool 
that is one of the most widely accepted and applied methods for 
project appraisal for large-scale infrastructure investments in 
the public sector because it provides many benefits including, 
a model of rationality, creating, evaluating and comparing 
alternatives including different scales for the alternatives, 
monetizing the costs and benefits and guiding decision makers 
(Jones et al., 2014).

When CBA is applied to investments in transportation, project 
scenario assumptions should be aware that these often have 
infinite lifetimes (Lee, 2002). Typical project lifetimes for public 
investment projects are Energy 25 years, Water and Environment 
30 years, Railways 30 years, Roads 25 years, Ports and Airports 
25 years, Telecommunications 15 years, Industry 10 years, Other 
Services 15 years (Jones et al., 2014).

Table 1 describe the investment of ground support equipment by 
diesel fuel and electric fuel which electric fuel more expensive 
than diesel fuel. In calculating the investment feasibility with 
NPV analysis several aspects are considered, namely income, 
expenses, net profit, discount rate, and the economic age of the 
product. The revenue used in this calculation represents the 
total operating income of Ground handling Company in various 
segments. The Ground Handling and AHAN segments contributed 
the highest to Ground handling Company operating income, 
which was around 76.9%. Meanwhile, the cargo warehousing 
and non-ground handling segments contributed 17.9% and 5.2% 
respectively. Therefore, investment in the GSE is indeed needed 
since this segment gives the highest income earned. Refers to an 
annual report published in 2013-2017, the financial statements 
show that yearly income increases by around 10% with the result 
that Company revenue is projected to increase every year by 10%. 
The Company expenditure on operational activities will also be 
estimated to increase by 10% annually. Projected increases in 
income and spending are also made because of the possibility of 
inflation every year (Table 2).

In the company’s profit and loss projection, revenue will be 
reduced by total expenses to find out the gross profit. After that, 
gross profit will also be subject to income tax of the business entity 

to find the net profit obtained, in accordance with government 
regulations that business income tax above 100 million rupiahs 
is 25% of the total taxable income (Gapura Angkasa, 2017). After 
calculating the profit and loss projection, it can be seen that the 
cash flow is mainly to see the comparison of the total cash in and 
cash out during the economic life of the tool for 20-25 years. 
This cash flow will facilitate us in calculating the parameters of 
investment feasibility. This analysis aims to compare the feasibility 
of investment for GSE products that use diesel fuel and electricity. 
Each product is assumed can be uses for 20 until 25 years with 
a discount rate of 3%. The results of the analysis can be seen as 
follows.

From the Table 3 above can be known there are no significant 
differences from investing in GSE Product that uses diesel fuel 
either electricity. There is no NPV value below 0, so investing in 
a product that uses diesel fuel or electricity is feasible. Investing 
products with useful life 25 years is the best choice since there is 
a huge gap between NPV value that assumed uses for 25 years and 
20 years. The GSE product that uses diesel fuel has the highest 
NPV score than others. Investing in a GSE product that uses diesel 
fuel for 25 years can be more profitable than NPV for a product 
that uses electricity.

3.1. The Feasibility in using Diesel Fuel for 25 and 20 
Years
In the use of e-GSE using diesel from 2017 to 2041, the prediction 
of 25 years of investing in diesel for profit and loss still has a 
margin of around 10% annually. In 2041, the net profit will reach 
USD 32,259,701.

In addition, the cash flow of diesel use for 25 years every year 
from 2017 to 2041 the expenditure will increase by 10% annually 

Table 1: Investment of Ground Support Equipment (GSE) 
in US Dollars
No Name Of GSE Diesel Fuel Electric
1 Pax Boarding Stair 26,000 40,285
2 Belt Conveyor Loader 25,000 40,000
3 Baggage Towing Tractor 32,500 42,000
4 High Lift Loader 23,000 37,000
5 Forklift 45,000 59,000
6 Push Back/ATT Wide Body 116,000 130,000
7 Ground Power Unit 180 KVA 32,000 44,000

Total Invest 299,500 392,285
Sources: Ground handling company

Table 2: The Income projection of Ground Handling 
Company 2017 to 2041
No Year Income/

year (USD)
No Year Income/

year (USD)
1 2017 120,133,309 14 2030 414,732,763
2 2018 132,146,639 15 2031 456,206,040
3 2019 145,361,303 16 2032 501,826,643
4 2020 159,897,434 17 2033 552,009,308
5 2021 175,887,177 18 2034 607,210,239
6 2022 193,475,895 19 2035 667,931,262
7 2023 212,823,484 20 2036 734,724,389
8 2024 234,105,833 21 2037 808,196,828
9 2025 257,516,416 22 2038 889,016,510
10 2026 283,268,058 23 2039 977,918,161
11 2027 311,594,863 24 2040 1,075,709,977
12 2028 342,754,350 25 2041 1,183,280,975
13 2029 377,029,785    
Sources : Ground Handling Company annual report, 2017 ( Process by the author) 

Table 3: The Projection feasibility cost in using diesel 
versus electricity (USD)
The GSE Product uses diesel 
fuel

The GSE Product uses 
electricity

25 years 20 years 25 years 20 years
196,296,805 128,476,615 196,268,647 128,452,391



Sari, et al.: The Optimization Using Electric Ground Support Equipment in Aviation Industry

International Journal of Energy Economics and Policy | Vol 12 • Issue 1 • 2022404

(Table 4). In 2041, the new cash flows will cost USD 32,271,681. 
The NPV value for investment in GSE products using diesel fuel 
assumes a useful life of 25 years (Gapura Angkasa, 2017).

NPV: Total PV- Total Investment
: Usd 196,596,305 – Usd 299,500
: Usd 196,296,805

Meanwhile, for the prediction of using e-GSE using diesel with an 
assumption of 20 years from 2017 to 2036, investing in diesel for 
profit and loss still has a margin of around 10% annually. In 2036, 
the net profit will reach USD 20,030,736 (Table 5). And cash flow 
from the use of diesel for 20 years every year from 2017 to 2041 
the expenditure will increase by 10% every year. By 2036, the new 
cash flows will cost USD 20,045,711 (Gapura Angkasa, 2017).

NPV: Total PV- Total Investment
: Usd 128,767,115 – Usd 299,500
: Usd 128,467,615

Meanwhile, for the prediction of using e-GSE using electricity 
with an assumption of 20 years from 2017 to 2036, investing 
in diesel for profit and loss still has a margin of around 10% 
annually. In 2036, the net profit will reach USD 20,030,736. 
And cash flow from the use of electricity for 20 years every 
year from 2017 to 2041 the expenditure will increase by 
10% every year. By 2036, the new cash flows will cost USD 
20,050,351.

3.2. The Feasibility in using Electric Fuel for 25 and 20 
Years
The use of e-GSE uses electric fuel from 2017 to 2041, the 
prediction that in 25 years investing in electric fuel for profit and 
loss still has a margin of around 10% annually. In 2041, net profit 
will reach USD 32,259,701 (Gapura Angkasa, 2017).

Meanwhile, cash flow from electricity use for 25 years each year 
from 2017 to 2041 expenditure will increase 10% annually. By 
2041, the net cash flow will cost USD 32,275,393 (Tables 6 and 7).

NPV: TotalPV- Total Investment
: Usd 196,660,932 – Us d 392,285

: Usd 196,268,647
NPV: Total PV- Total Investment
: Usd 128,844,676 – Usd 392,285
: Usd 128,452,391

There is some research literature on transportation using the 
BCA method. This method is used to predict time savings, 
the impact of the number of accidents, and reduction of noise 
disturbances. CBA is also used for transportation policy, which 
deals with environmental consequences such as CO2 emissions. 
In transportation studies using CBA, important issues discussed 
are time savings, increased traffic safety, other advantages of 
improving railroads. In several countries since 1981 the discount 
rate has decreased from 8% to 3.5% in 2012. It is quite difficult to 
select a discount value according to the project because it will be 
used as a parameter to calculate the present and future net value 
(Andersson et al., 2018).

4. DISCUSSION

From the finding, investing the electric ground support 
equipment in the ground handling company in Indonesia is 
feasible, even though investing a GSE product that uses diesel 
fuel for 25 years can be more profitable than uses electricity. 
This is not very surprising because Indonesia just began with the 
electricity vehicle and somehow less power in electricity. Also, 
Indonesia does not have a nuclear power. But with the support 
from the Indonesia government, Indonesia have willingness 
to start built electric vehicle industry and does not depend on 
fossil fuel.

Indonesia President announced with new regulation Number 
55/2019 to support the electric vehicle. Indonesia is committed to 
encouraging the acceleration of the battery-based motor vehicle 
program to support the realization and realization of reducing 
greenhouse gas emissions, increasing energy efficiency, energy 
security, and energy conservation in the transportation sector and 
realizing clean energy, clean air and environmentally friendly, and 
encouraging acceleration. Indonesia open up new and exciting 
business opportunities from the upstream to downstream supply 
chain that is needed to build the EV industry forward.

Table 4: Net Present Value Using Diesel Fuel in 25 Years
Year Interest PV Year Interest PV NPV
1 0.9709 4,251,164 15 0.6419 7,991,328 196,296,805
2 0.9426 3,407,201 16 0.6232 8,533,629
3 0.9151 3,637,481 17 0.605 9,112,128
4 0.8885 3,883,857 18 0.5874 9,731,049
5 0.8626 4,146,673 19 0.5703 10,391,859
6 0.8375 4,427,610 20 0.5537 11,097,652
7 0.8131 4,727,502 21 0.5375 11,849,612
8 0.7894 5,047,731 22 0.5219 12,655,642
9 0.7664 5,389,808 23 0.5067 13,515,153
10 0.7441 5,755,387 24 0.4919 14,431,845
11 0.7224 6,145,433 25 0.4776 15,412,955
12 0.7014 6,562,625
13 0.681 7,008,113
14 0.6611 7,482,864
   Total PV   196,596,305  



Sari, et al.: The Optimization Using Electric Ground Support Equipment in Aviation Industry

International Journal of Energy Economics and Policy | Vol 12 • Issue 1 • 2022 405

One of the airports that has become a role model for environmental 
sustainability is an airport in Sweden and the Scandinavian region. 
Swedish airports strive to minimize harmful emissions and slow 
down the global warming process. Swedish airports have the 
goal of achieving fossil oil free air transportation by 2045. Apart 
from airlines, the emission contributor in the aviation industry is 
GSE which is used to handle and serve aircraft. GSE operators 
are working to switch to equipment that reduces carbon. GSE 
investment is made with a combination of electricity, biogas and 
fossil fuel free (Airside International, 2019).

Meanwhile, investment in vehicles and equipment involves 
cooperation with several equipment providers and providing 
incentives for ground operators to use environmentally friendly 
vehicles. Another airport in Europe that is practicing zero emission 

in ground operations is Stutgart airport, Germany. This airport 
prioritizes vehicles that consume the most fossil fuels and occupy 
the largest emissions to be diverted to electric. The equipment are 
passenger bus, luggage tractor, and ground power unit.

Meanwhile, in Asia, there are Singapore and Hong Kong which 
have standards in supporting reducing emissions due to the use of 
GSE. Singapore, through the Changi Airport Group, collaborates 
with ground handling to reduce emissions at the airport by 
diverting the use of a fossil baggage tracktor to an electric baggage 
tractor. Currently, there are about 80 GSE machines operating at 
Changi Airport that use electric power.

Since 2017 Changi has started using electric GSE, and the result 
is that Changi can reduce 1000 tons of carbon dioxide emissions. 

Table 7: NPV for investing in The GSE product uses electricity (20 years)
Years Interest PV Years Interest PV NPV
1 0.9709 4,258,576.48 12 0.7014 6,567,980.16 128,452,391
2 0.9426 3,414,397.19 13 0.681 7,013,312.03
3 0.9151 3,644,466.88 14 0.6611 7,487,911.29
4 0.8885 3,890,640.30 15 0.6419 7,996,228.91
5 0.8626 4,153,257.94 16 0.6232 8,538,386.37
6 0.8375 4,434,004.04 17 0.605 9,116,746.79
7 0.8131 4,733,709.71 18 0.5874 9,735,533.43
8 0.7894 5,053,757.87 19 0.5703 10,396,212.33
9 0.7664 5,395,659.21 20 0.5537 11,101,879.14
10 0.7441 5,761,067.93
11 0.7224 6,150,948.37     
    Total PV  128,844,676  

Table 5: Net Present Value Using Diesel Fuel in 20 Years
Years Interest PV Years Interest PV NPV
1 0.9709 4,254,072 11 0.7224 6,147,597 128,467,615
2 0.9426 3,410,024 12 0.7014 6,564,726
3 0.9151 3,640,222 13 0.681 7,010,153
4 0.8885 3,886,518 14 0.6611 7,484,844
5 0.8626 4,149,256 15 0.6419 7,993,251
6 0.8375 4,430,119 16 0.6232 8,535,495
7 0.8131 4,729,938 17 0.605 9,113,940
8 0.7894 5,050,096 18 0.5874 9,732,808
9 0.7664 5,392,104 19 0.5703 10,385,026
10 0.7441 5,757,616 20 0.5537 11,099,310
    Total PV 128,767,115  

Table 6: Net Present Value in Investing Electric Fuel For 25 Years
Years Interest PV Years Interest PV NPV
1 0.9709 4,254,768 14 0.6611 7,485,318 196,268,647
2 0.9426 3,410,700 15 0.6419 7,993,711
3 0.9151 3,640,877 16 0.6232 8,535,942
4 0.8885 3,887,155 17 0.605 9,114,373
5 0.8626 4,149,874 18 0.5874 9,733,229
6 0.8375 4,430,719 19 0.5703 10,393,975
7 0.8131 4,730,520 20 0.5537 11,099,707
8 0.7894 5,050,661 21 0.5375 11,851,607
9 0.7664 5,392,653 22 0.5219 12,657,579
10 0.7441 5,758,149 23 0.5067 13,517,034
11 0.7224 6,148,115 24 0.4919 14,433,670
12 0.7014 6,565,229 25 0.4776 15,414,728
13 0.681 7,010,641
    Total PV  196,660,932  



Sari, et al.: The Optimization Using Electric Ground Support Equipment in Aviation Industry

International Journal of Energy Economics and Policy | Vol 12 • Issue 1 • 2022406

An example of how GSE can reduce carbon is the Ground Power 
Unit (GPU) tool to reduce about 90% CO2 and 95% NOx.

Currently, the new eco-airport concept has been developed in five 
airports in Indonesia, namely Soekarno Hatta (Jakarta), Juanda 
(Surabaya), Ngurah Rai (Denpasar), Hang Nadim (Batam), dan 
Sultan Mahmud Badarudin II (Palembang).

5. CONCLUSION

The aim of this research is to conduct the feasibility study of the 
usage e GSE for ground support equipment in aviation industry 
using benefit cost analysis. Based on the results of the study, it 
shows that the use of e-GSE using both diesel and electricity is 
feasible because it has an NPV value of more than 0, so investing 
in products that use diesel or electricity is possible. Investments in 
products with a useful life of 25 years are the best choice because 
there is a large gap between the NPV values   that are assumed to be 
used for 25 years and 20 years. GSE products that use diesel have 
the highest NPV value compared to other products. Investing in 
GSE products that use diesel for 25 years can be more profitable 
than NPV for products that use electricity.

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