Citation: Amupolo, A.;

Nambundunga, S.; Chowdhury,

D.S.P.; Grün, G. Techno-Economic

Feasibility of Off-Grid Renewable

Energy Electrification Schemes: A

Case Study of an Informal Settlement

in Namibia. Energies 2022, 15, 4235.

https://doi.org/10.3390/en15124235

Academic Editors: Zhengmao Li,

Tianyang Zhao, Ke Peng, Jinyu Wang,

Zao Tang and Sumedha Sharma

Received: 14 April 2022

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energies

Article

Techno-Economic Feasibility of Off-Grid Renewable Energy
Electrification Schemes: A Case Study of an Informal
Settlement in Namibia
Aili Amupolo 1,2,*, Sofia Nambundunga 1, Daniel S. P. Chowdhury 3 and Gunnar Grün 2

1 Department of Electrical and Computer Engineering, Namibia University of Science and Technology,
Windhoek 13388, Namibia; 201028336@students.nust.na

2 Institute of Acoustics and Building Physics, University of Stuttgart, 70569 Stuttgart, Germany;
gunnar.gruen@iabp.uni-stuttgart.de

3 Department of Electrical Engineering, Nelson Mandela University, Port Elizabeth 6031, South Africa;
spchowdhury2010@gmail.com

* Correspondence: ashigwedha@nust.na

Abstract: This paper examines different off-grid renewable energy-based electrification schemes for
an informal settlement in Windhoek, Namibia. It presents a techno-economic comparison between
the deployment of solar home systems to each residence and the supplying power from either a
centralized roof-mounted or ground-mounted hybrid microgrid. The objective is to find a feasible
energy system that satisfies technical and user constraints at a minimum levelized cost of energy
(LCOE) and net present cost (NPC). Sensitivity analyses are performed on the ground-mounted
microgrid to evaluate the impact of varying diesel fuel price, load demand, and solar photovoltaic
module cost on system costs. HOMER Pro software is used for system sizing and optimization.
The results show that a hybrid system comprising a solar photovoltaic, a diesel generator, and
batteries offers the lowest NPC and LCOE for both electrification schemes. The LCOE for the smallest
residential load of 1.7 kWh/day and the largest microgrid load of 5.5 MWh/day is USD 0.443/kWh
and USD 0.380/kWh, respectively. Respective NPCs are USD 4738 and USD 90.8 million. A sensitivity
analysis reveals that variation in the fuel price and load demand changes linearly with system costs
and capacities. However, reducing the PV module price in an energy system that includes wind
and diesel power sources does not offer significant benefits. Furthermore, deploying an energy
system that relies on fossil fuels to each residence in an informal settlement is not environmentally
responsible. Unintended negative environmental impacts may result from the mass and simultaneous
use of diesel generators. Therefore, a microgrid is recommended for its ability to control the dispatch
of diesel generation, and its scalability, reliability of supply, and property security. A roof-mounted
microgrid can be considered for piloting due to its lower initial investment. The electricity tariff
also needs to be subsidized to make it affordable to end-users. Equally, government and community
involvement should be prioritized to achieve long-term economic sustainability of the microgrid.

Keywords: hybrid energy system; techno-economic; off-grid; electrification; microgrid; informal
settlement; HOMER; levelized cost of energy; net present cost; case study

1. Introduction

Access to electricity is an essential stimulant to improved productivity, enhanced
living standards, and promotion of various types of social–economic welfare [1–3]. Whilst
the proportion of those without electricity in sub-Saharan Africa has steadily declined [4],
about 45% of the people in Namibia still lack access to electricity [5], especially those living
in rural areas and informal settlements. The country’s electricity access for rural and urban
areas is 34.9% and 74.6%, respectively [6]. The disparity has motivated many people to
migrate from rural to urban settings in pursuit of better opportunities [7]. They often

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Energies 2022, 15, 4235 2 of 32

settle in informal settlements due to unemployment, low incomes, and other economic
challenges. Due to a lack of affordable housing and declining economic opportunities
owing to the impacts of the COVID-19 pandemic, informal settlements have also become
home to middle-class citizens who otherwise could reside in better suburbs [8,9].

Informal settlements are typically semi- or un-serviced peri-urban areas on the out-
skirts of municipal boundaries. Weber et al. [10] classify informal settlements as either:
(i) structured settlements, (ii) unstructured settlements with high density, or (iii) uncon-
trolled urban expansions where residents set up illegal and informal housing structures,
often made of low-cost corrugated iron. Where informal settlements are recognized by
local authorities, road layouts are structured, and basic essential services such as water,
sanitation, and electricity are provided. Thus, their “informality” is due to them not being
formally proclaimed and also because residents do not have registered land tenure [11].
However, most informal settlements in Namibia are without electricity and other essential
services that could improve residents’ living conditions and social status [12]. Studies
have shown that access to electricity can influence the aspirations of people living in rural
and informal settlements towards a productive life [13–15], better education [16,17], and
increased health [18–20]. Thus, providing electricity to informal settlements is expected to
reduce poverty and indirectly contribute to the country’s socio-economic development.

Although the Namibian government has made efforts to electrify rural and informal
settlements through traditional grid extension, various challenges have deterred the efforts.
Firstly, a large investment is needed to extend the national grid for a country as wide
and low-densely populated as Namibia [21–23]. Secondly, development has not kept pace
with the rapid growth of informal settlements. Thirdly, domestic generation is not enough
to meet the country’s existing demand, let alone the additional load expected from grid
expansions. Currently, about 60% of national demand [24] is met by electricity imports
from neighboring countries such as South Africa, through the Southern African Power Pool
(SAPP) [25]. With increasing regional demand [26], SAPP energy deficits could soon affect
Namibia’s energy security and further slow down economic growth. It is thus prudent that
Namibia considers renewable energy supplies to mitigate the existing power shortage and
extend electricity services to rural and informal settlements.

Worldwide deployment of renewable energy systems has drastically increased in the
past decade, owing to reduced components cost [27,28], technological advancements [29],
global environmental concerns [30], market growth [31], and policy support [32]. For
instance, the global average cost of crystalline silicon photovoltaic modules has drastically
fallen by 85% between 2010 and 2020 [33]. Subsequently, the installed cost of utility-scale,
commercial-rooftop, and residential photovoltaic systems has reduced by 82%, 69%, and
64%, respectively [34]. Installed cost includes the cost of equipment, site preparation, and
installation of equipment. In general, total installed costs vary for different countries and
regions but largely depend on project size, location, maturity of the market, and financing
scheme [35].

In the next sub-sections, this paper provides a brief assessment of renewable energy po-
tential in Namibia, the country’s current power generation capacity, problem identification
and objectives, and contributions of this study.

1.1. Potential Renewable Resources in Namibia

Namibia is geographically located in the south-west of Africa, bordering Angola
(north), South Africa (south), the Atlantic Ocean (west), and Botswana (east). It has a
land area of 825,615 km2, a population of about 2.5 million [36], and a diverse terrain
with a mostly semi-arid climate characterized by irregular rainfall and large temperature
differences in day and night times [37,38]. The country has extensive and untapped
renewable energy resources for electricity production, which include hydro, solar, wind,
biomass, and natural gas [39], as outlined below:



Energies 2022, 15, 4235 3 of 32

• The hydro resource is currently the largest renewable source contributing to domesti-
cally generated electricity. In 2021, the only hydropower plant in the country (Ruacana)
contributed 80% of domestic capacity [5,24].

• Namibia receives abundant solar radiation, with daily global horizontal irradiation
between 4.4 kWh/m2 along the coastal areas and roughly 7.8 kWh/m2 in arid areas.
A pre-feasibility study established that more than 33,000 km2 of potential sites for
concentrated solar power exist in the country and produce up to 250 GWe [40,41].

• Average wind speed in the country ranges from 4 to 15 m/s, with higher speed
expected along the coastline. A wind-power density of class 7 can be expected on the
Luderitz coastline and class 3 in most parts of the country [42].

• Encroacher bush and solid waste are key biomass resources in Namibia for electricity
generation. There are approximately 260 billion m2 of bush-encroached land in the
country and it is expected to grow by 3.2% annually [43].

• A natural gas field with the potential for an 800 MW (nominal) power plant was
discovered in offshore Namibia, but its implementation remains elusive [44].

1.2. Overview of the Namibian Power Sector

Namibia’s average peak demand is about 688 MW, and is largely met by a local/import
ratio of about 40/60. The 40% local generation is comprised of hydro (≈80%), coal
(≈2.5%), and solar/wind/biomass (≈17.5%) [5,25]. Though local installed capacity is
about 639.5 MW, as shown in Table 1, the hydro generation is a run of the river plant
whose throughput depends on rainfall patterns. Therefore, energy shortage could be up
to 60% and is often met by electricity imports from the region [25,45]. To reduce imports
dependency, the government, (i) implemented a modified single buyer market framework
that promotes participation from independent power producers [46], (ii) increased the
renewable share [46,47], and (iii) improved governing policies that attract more energy
investments [48,49]. Consequently, Namibia’s solar photovoltaic market has grown [50,51],
and deployment of more than 278 MW of renewable capacity is expected within the next
5 years [24]. However, more effort is still needed to harness abundant renewable sources to
ensure self-sufficiency and achieve universal electricity access, including electrification of
informal settlements.

Table 1. Existing power production plants in Namibia [25].

Power Plant Type Built Capacity (MW) Operating Modus

Ruacana Hydro 1978 347 Flexible/Baseload
Van Eck Coal 1973 90 Stand-by
Anixas Diesel 2011 22.5 Stand-by
IPPs 1 Solar vary 174.5 Flexible

IPPs 1—Ombepo Wind 2019 5 Flexible
IPPs 1—N-BiG Biomass 2010 0.5 Flexible

Total Capacity (MW) 639.5
1 IPP—Independent Power Producers.

1.3. Problem Identification and Study Objectives

Existing and planned renewable generation in Namibia is primarily via large-scale
power plants feeding into the national grid and located far from loads. This necessi-
tates large capital investments, and lengthy procurement and construction processes. The
upgrading of network infrastructure is also inevitable to integrate large and varying re-
newable energy, and also mitigate possible grid instability. Meantime, the country’s energy
demand increases [39] and unelectrified informal settlements grow rapidly [10], thus posing
irrepressible socio-economic challenges [52].

In the wake of the declining cost of renewable energy components and vast research
on renewable grid integrations, the energy sector is now favoring solar home systems
(SHS) and microgrids as a means to reduce capital costs [53], provide rapid electrifica-



Energies 2022, 15, 4235 4 of 32

tion [54,55], and increase network reliability and resiliency [56,57]. Generally, both SHS
and microgrids are relatively “small grids” that integrate distributed energy resources
such as solar photovoltaics, distributed energy storage devices such as batteries, and local
loads. They, however, differ in generation capacity, control strategies, and ability to operate
autonomously or in parallel with the grid for better reliability and resiliency [58]. Micro-
grids tend to have better features and are commonly sized between 50 kW and multiple
megawatts [59].

In view of the above, this study examines the technical and economic conditions
under which the deployment of solar home systems and microgrids becomes cost effective
and viable for a peri-urban area in a developing country. The study is limited to off-grid
configurations for an informal settlement in Namibia and assesses whether electrification
from a centralized microgrid or stand-alone solar home systems for each resident would be
cheaper, sustainable, and environmentally friendly. A sensitivity analysis is also conducted
to assess the impact of changes in the diesel fuel price, load demand, and solar PV module
costs on optimal energy systems.

The study employs HOMER (Hybrid Optimization of Multiple Energy Resources)
software to find optimal energy systems that can cost-effectively satisfy load demand by
minimizing the net present cost (NPC) and levelized cost of energy (LCOE). NPC refers to
the difference between the present value of all costs of installing and operating a renewable
energy system and savings or revenues earned over the project’s lifetime. LCOE is a
cost-per-unit measure (USD/kWh) that compares the competitiveness of generating energy
from different systems. Furthermore, HOMER is a widely used micro-power simulation
software that employs an iterative optimization algorithm to find a feasible off-grid or
on-grid energy solution [60].

1.4. Study Contributions

This study contributes the following:

• It examines different off-grid energy configurations that can supply the load profile
expected in a typical informal settlement or peri-urban community.

• It presents a comparative analysis of the deployment of individual solar home systems
to each resident versus supplying electricity from a centralized microgrid.

• It implements a “framework for rural energy system design” proposed by Ali et al. [61]
and assesses its performance for an informal settlement.

• It provides a holistic feasibility study that considers both technical, economic, social,
and governance aspects in determining the optimal and practical energy solution for
the selected community.

• It provides insight on whether an off-grid renewable energy system designed for an
informal settlement will have techno-economic characteristics similar to a rural area,
an urban area, or otherwise.

• It can inform power system planners, policy makers, energy investors, and other
researchers on the technical and economic conditions to electrify a peri-urban area
using renewable energy sources.

This paper is structured into five main sections. Section 1 provides an introduction, the
renewable energy potential and power sector overview in Namibia, and the study objectives
and contributions. Section 2 discusses recent related techno-economic studies. Section 3
detailed the steps to optimal sizing and techno-economic assessment of a renewable energy
system. Section 4 discusses simulation results, while Section 5 concludes the study and
provides recommendations.

2. Related Techno-Economic Studies on Hybrid Renewable Energy Systems

Techno-economic optimization of off-grid and on-grid hybrid renewable energy sys-
tems (HRES) has drawn immense attention from researchers in recent years. Most studies
examined different HRES configurations to determine optimal options for specific loads
such as residential, rural villages, industrial, islands, and medical facilities. An optimal



Energies 2022, 15, 4235 5 of 32

solution is the one that can sufficiently meet the load at the lowest cost. Common criteria
used in evaluating the economic performance of HRES include net present cost (NPC),
levelized cost of energy (LCOE), discounted payback period, and carbon dioxide emission
rates [62,63].

Generally, optimal HRES integrates various renewable sources, such as solar pho-
tovoltaic and wind, conventional generation such as a diesel generator, and/or energy
storage devices, and local loads into a single power system, as depicted in Figure 1. Such
configurations can exploit the difference in seasonal and daily profiles of renewable power
sources, such that their complimentary behaviors can results in improved reliability of sup-
ply while reducing system energy cost [60,64]. Integrating energy storage such as batteries
and fuel cells is also found to improve system reliability and stability by countering the
effect of fluctuating, and unpredictability of, output power from renewable sources [65].

Energies 2022, 15, x FOR PEER REVIEW 5 of 32 
 

 

examined different HRES configurations to determine optimal options for specific loads 
such as residential, rural villages, industrial, islands, and medical facilities. An optimal 
solution is the one that can sufficiently meet the load at the lowest cost. Common criteria 
used in evaluating the economic performance of HRES include net present cost (NPC), 
levelized cost of energy (LCOE), discounted payback period, and carbon dioxide emission 
rates [62,63]. 

Generally, optimal HRES integrates various renewable sources, such as solar photo-
voltaic and wind, conventional generation such as a diesel generator, and/or energy stor-
age devices, and local loads into a single power system, as depicted in Figure 1. Such con-
figurations can exploit the difference in seasonal and daily profiles of renewable power 
sources, such that their complimentary behaviors can results in improved reliability of 
supply while reducing system energy cost [60,64]. Integrating energy storage such as bat-
teries and fuel cells is also found to improve system reliability and stability by countering 
the effect of fluctuating, and unpredictability of, output power from renewable sources 
[65]. 

 
Figure 1. An example of an off-grid hybrid renewable energy system (HRES). 

Table 2 provides a summary of some recent studies on the techno-economic viability 
of off-grid hybrid renewable energy systems (HRES) for different load profiles. It outlines 
each study’s main objective, load type, optimization tool employed, and key findings of 
the research. Generally, most studies found HRES to be the optimal choice as it effectively 
improves the energy usage factor [66], enhances supply reliability [67], reduces energy 
storage requirements [64], and lowers carbon emission [68]. A review of selected research 
is expanded in the next paragraphs. 

Ali et al. [61] developed a design framework that can be used to structure a techno-
economic feasibility study for a rural energy system. The framework was implemented to 
design potential off-grid and on-grid HRES for a village in Dera Ismail Khan, Pakistan, 
and examined its potential for benchmarking in other developing countries. Real-time 
electrical load data were used, and HOMER software was employed to carry out system 
optimization and techno-economic feasibility. The system’s robustness and commercial 
viability were tested via a sensitivity analysis that considered the impacts of solar photo-
voltaic modules’ derating factor and various macro-economic variables. The study found 
a grid-integrated HRES to offer lower costs than an off-grid configuration, at a levelized 
cost of energy between USD 0.072/kWh and USD 0.078/kWh, which was also lower than 
the existing utility tariff. The best solution included a solar photovoltaic source, battery 
storage, a diesel generator, and restricted grid-connection time that reliably caters for fre-
quent power outages. 

Figure 1. An example of an off-grid hybrid renewable energy system (HRES).

Table 2 provides a summary of some recent studies on the techno-economic viability
of off-grid hybrid renewable energy systems (HRES) for different load profiles. It outlines
each study’s main objective, load type, optimization tool employed, and key findings of
the research. Generally, most studies found HRES to be the optimal choice as it effectively
improves the energy usage factor [66], enhances supply reliability [67], reduces energy
storage requirements [64], and lowers carbon emission [68]. A review of selected research
is expanded in the next paragraphs.

Ali et al. [61] developed a design framework that can be used to structure a techno-
economic feasibility study for a rural energy system. The framework was implemented
to design potential off-grid and on-grid HRES for a village in Dera Ismail Khan, Pakistan,
and examined its potential for benchmarking in other developing countries. Real-time
electrical load data were used, and HOMER software was employed to carry out system
optimization and techno-economic feasibility. The system’s robustness and commercial
viability were tested via a sensitivity analysis that considered the impacts of solar photo-
voltaic modules’ derating factor and various macro-economic variables. The study found a
grid-integrated HRES to offer lower costs than an off-grid configuration, at a levelized cost
of energy between USD 0.072/kWh and USD 0.078/kWh, which was also lower than the
existing utility tariff. The best solution included a solar photovoltaic source, battery storage,
a diesel generator, and restricted grid-connection time that reliably caters for frequent
power outages.

Uddin et al. [69] investigated the technical, economic, and environmental feasibility
of a 1.4 MW microgrid that employed recently innovated floating solar photovoltaic mod-



Energies 2022, 15, 4235 6 of 32

ules to serve a remote coastal region in Bangladesh. The load included 2500 households,
120 electric-vehicle scooters, and a 25,000 L water treatment facility. Techno-economic sim-
ulation and analysis of system electrical characteristics such as bus voltage were conducted
using HOMER and MATLAB/Simulink software, respectively. A configuration of floating
solar photovoltaic and battery storage system was found to reliably serve the load at USD
0.183/kWh, which was consistent with the region’s grid tariff. The microgrid could also
result in an annual saving of up to 694.56 metric tons of carbon dioxide emissions (CO2).

In [70], three potential off-grid HRES were compared to determine the configuration
that would reliably and cost-effectively supply a commercial load for a remote transport
facility in Makkah Province, Saudi Arabia. A techno-economic assessment was performed
using HOMER software, and the best solution was a combination of wind as a power
source, batteries and fuel cells for storage, and a diesel generator for backup supply. Its
levelized cost of energy was USD 0.271/kWh.

Mehta and Chowdhury [71], investigated the technical and economic feasibility of
an optimal HRES for medical facilities in Tanzania. Analysis was carried out using the
renowned HOMER software. It was observed that an optimal HRES at both locations
included a solar photovoltaic, a diesel generator, and battery storage, presenting lower
NPC and LCOE. The total system cost was USD 63,136.93 and USD 51,544.75 for an average
daily load of 20.26 kWh/day and 16.22 kWh/day for hospitals in the districts of Upanga
and Ngamiani, respectively. The fuel cost was between 12.3% and 13.3% of the overall
system cost, implying cleaner energy production.

In a study by Zebra et al. [72], a review was conducted to identify key opportunities
and barriers to HRES implementation in developing countries. The study considered
political/policy, economic, social, technological, environmental, and legal (PESTEL) issues
that could influence the integration of HRES in different countries. Information was
obtained from scientific literature, development reports, and semi-structured qualitative
interviews with experts. The study revealed that on-grid utility-scaled solar photovoltaic
microgrids offer lowest the LCOE, ranging between USD 0.54/kWh and USD 0.77/kWh. It
was further shown that community and government support were key to the successful
implementation of HRES solutions.

A techno-economic study for a rural community in Fouay, Benin, found an off-grid
hybrid solar photovoltaic, diesel generator, and battery system to offer the lowest LCOE of
USD 0.207/kWh. Analysis was performed using HOMER software and established that
integrating a diesel generator increased supply reliability and reduced battery requirements
by 70% compared to a solar photovoltaic and battery configuration [73].

Krishan and Suhag [74] compared the techno-economic performance of three hybrid
renewable energy systems for residential and agricultural loads in the Yamunanagar com-
munity in the State of Haryana, India. HOMER and MATLAB/Simulink software were
used for techno-economic evaluation and analysis of electrical systems, respectively. The
result showed that an energy system that combines solar, wind, and battery was cost-
effective for the selected site, with an LCOE of USD 0.288/kWh. The MATLAB simulation
demonstrated that an active power balance was maintained amidst solar irradiance, load,
and wind speed variations. Similarly, Javed et al. [75], developed a genetic optimization
algorithm to evaluate the technical and economic viability of a hybrid solar, wind, and
battery system for a remote island. The algorithm was compared to HOMER optimization
and offered better performance, in terms of supply reliability and cost. The selected en-
ergy configuration could sufficiently supply load, but with high initial capital costs. The
study also observed that the size of a wind turbine had little impact on the system cost
and reliability.

It is evident from past research that the subject of assessing the viability of renewable
energy systems continues to evolve. Literature shows that there is no single solution. An
optimal solution is influenced by factors such as accuracy of load profiles [70], types of
renewable energy resources at the site [61], component costs [28], and an optimization
method used [68]. Government and community support are also key to the implementation



Energies 2022, 15, 4235 7 of 32

and economic sustainability of these projects [76,77]. Therefore, each case study is expected
to present unique constraints and outcomes.

Table 2. Selected research on off-grid hybrid renewable energy systems (HRES), published between
2018 and 2022 *.

No Year Case Study Load Type Objective and
Optimization Tool(s) Key Findings

1 2022 Bangladesh [69]
Remote

western coastal
region

- Investigated the technical,
economic, and environmental
feasibility of a 1.4 MW solar
mini-grid to serve 2500
households, 120 electrical
scooters, and a 25,000 L water
treatment facility.

- Used MATLAB and HOMER
software

- A floating PV|BAT system
could optimally serve the load
at an LCOE of USD
0.183/kWh, which is found to
be in line with the region’s
grid tariff.

- Annual carbon dioxide
emissions (CO2) of 466.56 and
228 metric tons could also be
saved from EV scooters and
households, respectively.

2 2022 Makkah Province,
Saudi Arabia [70]

Remote
commercial

facility

- Evaluated the
techno-economic feasibility of
three possible off-grid HRES
systems for a commercial load
of a remotely located
transport company.

- HOMER software.

- A WT|DG|FC|BAT system
was the most optimal and
eco-friendly option at NPC of
USD 7.045 million and LCOE
of USD 0.271/kWh.

3 2021 Dera Ismail Khan,
Pakistan [61]

Semi-
electrified

village

- Developed and implemented
a design framework for a
rural electrification system.
Techno-economic viability of
two off-grid and two on-grid
configurations was performed
using HOMER software

- A grid-connected hybrid solar
PV, batteries, and diesel
generator was the
economically feasible solution.
Excess energy is traded with
the grid.

- LCOE for on-grid systems
were USD 0.072/kWh and
USD 0.078/kWh, and USD
0.145/kWh and USD
0.167/kWh for the off-grid
options.

4 2021
Upanga and
Ngamiani,

Tanzania [71]

Medical
facilities

- Investigated the technical,
economic, and environmental
feasibility of an optimal HRES
for medical facilities in
Tanzania.

- HOMER software was used.

- The PV|DG/BAT option was
the most optimal HRES
option, presenting lower NPC,
LCOE, and excess electricity.



Energies 2022, 15, 4235 8 of 32

Table 2. Cont.

No Year Case Study Load Type Objective and
Optimization Tool(s) Key Findings

5 2021
Various

Developing
Countries [72]

Rural
communities

- Compared the
techno-economic performance
of a range of off-grid HRES
systems to electrify rural
communities in various
developing countries.

- Used PESTEL analytical
framework

- A PV|DG system was the
most optimal solution for
most locations.

- LCOE for this option ranged
between (USD 0.54/kWh and
USD 0.77/kWh.

- It was further established that
community and government
supports were key to the
successful implementation of
off-grid HRES solutions.

6 2020 Benin, Africa [73] Remote village

- Evaluated the technical, and
economic feasibility of a
hybrid off-grid option for a
remote village in Benin.

- Used HOMER software.

- A PV|DG|BAT was the least
cost option at an LCOE of
USD 0.207/kWh and reduced
battery storage requirements
by 70%.

7 2019
Chungbuk

Innovation City,
South Korea [78]

Town

- Assessed the environmental
economic impact of an HRES
for a town in South Korea,
which included electrical and
thermal load.

- Used HOMER software.

- When compared to
conventional systems, a
system with a higher solar
fraction could result in CO2
reduction of up to 61%,
energy savings of up to 73%, a
cost/benefit ratio of 1.7, and a
lower LCOE.

8 2019
Jiuduansha,

Near Shanghai,
China [75]

Remote island

- Evaluated the technical and
economic viability of a hybrid
solar-wind-battery system.

- Used a genetic algorithm and
HOMER

- Hybrid PV|WT/BAT systems
could sufficiently electrify an
island without violating any
constraints but with high
initial capital requirements.

- The size of a wind turbine
had little impact on the
system cost and reliability.

9 2019 Maluku Province,
Indonesia [79]

Remote
villages

- Compared the viability of
different HRES systems for 3
villages in Maluku province,
Indonesia.

- HOMER, PVsyst, and PVsol
were used.

- The PV|DG option was the
most optimal solution for
Klistau village, while the
PV|WT/DG was found to be
optimal for Wairatan and
Leiting villages.

10 2019 Yamunanagar,
India [74]

Rural
community

- Investigate the
techno-economic viability of
an HRES system for
residential and agriculture
load. Impact of renewable
source variability on HRES
electrical characteristics was
also assessed.

- Used HOMER and
MATLAB/Simulink software

- The hybrid PV|WT|BAT was
the most cost-effective option
for the site.

- Active power balance and
voltage buses were
maintained in spite of solar
irradiance, wind speed, and
load variations.



Energies 2022, 15, 4235 9 of 32

Table 2. Cont.

No Year Case Study Load Type Objective and
Optimization Tool(s) Key Findings

11 2018 Godagari,
Bangladesh [80] Remote areas

- Evaluated the performance of
the PV|DG/BAT option for a
remote community, mainly
focusing on the effects of
different battery dispatching
strategies on LCOE and NPC.

- Used HOMER software

- Combined dispatch strategy
had resulted in lower LCOE
compared to the load
following and cyclic charging
strategies

12 2018 Mbeni,
Comoros [81] Remote island

- Investigated the
techno-economic viability of a
renewable-based microgrid
with hydrogen storage,
primarily to mitigate
electricity deficits and load
shedding in a rural area in
Comoros.

- HOMER software was used

- A microgrid comprised of
PV|DG|WT|FC|Electrolyser|
Hydrogen storage tank was
found to fully serve the load
with excess electricity of
538,138 kWh/year.

- Although the solution
eliminated energy deficiency
and intermittency, the LCOE
was 8.4% above the current
grid tariff.

* Abbreviations used in this table are listed below: HOMER—Hybrid Optimization of Multiple Energy Resources,
HRES—hybrid renewable energy system, NPC—net present cost, LCOE—levelized cost of energy, PESTEL—
political/policy, economic, social, technological, environmental, and legal, PV—solar photovoltaic, DG—diesel
generator, WT—wind turbine, BAT—battery storage system, FC—fuel cell, PVsyst—a photovoltaic energy design
and simulation software, PVsol—a photovoltaic energy design and simulation software.

3. Materials and Methods

This study implements a framework proposed by Ali et al. in assessing the techno-
economic viability of a rural energy system. The emphasis is on ensuring that input
requirements are carefully assessed to ensure that an appropriate energy system is designed
for the target community. As depicted in Figure 2, a pre-HOMER input assessment is
carried out in the first step. This includes (i) examining the selected site’s social and
economic conditions; (ii) assessing the community load demand pattern; (iii) assessing site-
specific renewable energy resources; and (iv) defining energy system component capacities
and costs.

In the second step, HOMER Pro 3.14.7880.21077 by HOMER Energy, LLC (Boulder,
CO, USA) is used to carry out the techno-economic analysis by modeling, simulating,
and optimizing different energy configurations. The aim is to determine the optimal
capacities of generating units that can cost-effectively meet the load demand. In the third
step, a sensitivity analysis is conducted to assess the robustness of the optimal energy
configuration. Finally, financial, social, and environmental aspects are briefly assessed to
determine the social and commercial efficacy of the most economical energy system.



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Energies 2022, 15, x FOR PEER REVIEW 9 of 32 
 

 

12 2018 Mbeni, Comoros 
[81] 

Remote island 

- Investigated the techno-economic 
viability of a renewable-based mi-
crogrid with hydrogen storage, 
primarily to mitigate electricity 
deficits and load shedding in a ru-
ral area in Comoros. 

- HOMER software was used 

- A microgrid comprised of 
PV|DG|WT|FC|Electro-
lyser|Hydrogen storage 
tank was found to fully 
serve the load with excess 
electricity of 538,138 
kWh/year.  

- Although the solution elim-
inated energy deficiency 
and intermittency, the 
LCOE was 8.4% above the 
current grid tariff.  

* Abbreviations used in this table are listed below: HOMER—Hybrid Optimization of Multiple En-
ergy Resources, HRES—hybrid renewable energy system, NPC—net present cost, LCOE—levelized 
cost of energy, PESTEL—political/policy, economic, social, technological, environmental, and legal, 
PV—solar photovoltaic, DG—diesel generator, WT—wind turbine, BAT—battery storage system, 
FC—fuel cell, PVsyst—a photovoltaic energy design and simulation software, PVsol—a photovol-
taic energy design and simulation software. 

3. Materials and Methods 
This study implements a framework proposed by Ali et al. in assessing the techno-

economic viability of a rural energy system. The emphasis is on ensuring that input re-
quirements are carefully assessed to ensure that an appropriate energy system is designed 
for the target community. As depicted in Figure 2, a pre-HOMER input assessment is car-
ried out in the first step. This includes (i) examining the selected site’s social and economic 
conditions; (ii) assessing the community load demand pattern; (iii) assessing site-specific 
renewable energy resources; and (iv) defining energy system component capacities and 
costs. 

 
Figure 2. The techno-economic analysis process using HOMER. 

In the second step, HOMER Pro 3.14.7880.21077 by HOMER Energy, LLC (Boulder, 
CO, USA) is used to carry out the techno-economic analysis by modeling, simulating, and 
optimizing different energy configurations. The aim is to determine the optimal capacities 
of generating units that can cost-effectively meet the load demand. In the third step, a sen-
sitivity analysis is conducted to assess the robustness of the optimal energy configuration. 

Figure 2. The techno-economic analysis process using HOMER.

3.1. Site Socio-Economic Assessment

The case study is a semi-electrified Havana informal settlement located on the outskirts
of Katutura, a suburb in the northern part of Windhoek, the Namibian capital city (shown
in Figure 3). The site is geographically located at 22◦29′ S, 17◦01′ E, at 1558 m in elevation.
It is in a semi-arid climatic region with hot summers and cold to mild winters [38]. Havana
is the most populous and one of the oldest informal settlements in Windhoek, spanning
a total area of approximately 3.1 km2 and a dwelling density of around three dwellings
per 100 m2. The settlement is mainly for rural migrants, but it has also become a residence
for anyone seeking low-cost living in the city [82]. This is because authorities are slow
in delivering proper, sufficient, and affordable housing at a rate that keeps pace with the
influx and increasing living costs.

Energies 2022, 15, x FOR PEER REVIEW 10 of 32 
 

 

Finally, financial, social, and environmental aspects are briefly assessed to determine the 
social and commercial efficacy of the most economical energy system. 

3.1. Site Socio-Economic Assessment 
The case study is a semi-electrified Havana informal settlement located on the out-

skirts of Katutura, a suburb in the northern part of Windhoek, the Namibian capital city 
(shown in Figure 3). The site is geographically located at 22°29′ S, 17°01′ E, at 1558 m in 
elevation. It is in a semi-arid climatic region with hot summers and cold to mild winters 
[38]. Havana is the most populous and one of the oldest informal settlements in Wind-
hoek, spanning a total area of approximately 3.1 km2 and a dwelling density of around 
three dwellings per 100 m2. The settlement is mainly for rural migrants, but it has also 
become a residence for anyone seeking low-cost living in the city [82]. This is because 
authorities are slow in delivering proper, sufficient, and affordable housing at a rate that 
keeps pace with the influx and increasing living costs. 

 
Figure 3. Havana informal settlement terrain and characteristics. 

Although many residents have the means to construct decent housing, houses in the 
informal settlements are mainly constructed of cheap and uninsulated corrugated iron 
that can easily be erected or removed [10]. This is because most of the informal settlers 
lack formal property rights and are therefore at risk of losing their investments in event 
of eviction from the land. However, the Havana settlement has been proclaimed a city 
structure and basic services are gradually being rolled out. This includes electrification of 
Havana Ext 1–3 in 2020/2021 through the “Windhoek Peri-Urban Electrification Project” 
[83–85]. Since service delivery has not kept pace with rapid growth of informal settle-
ments, illegal electricity connections have been on the rise as the un-electrified residents 
try to connect from those legally supplied [86–88]. 

Available data from 2004 estimated that 29% of the Windhoek population lived in 
informal settlements [89]. Since the Windhoek population has grown annually by 4.2% 
between 1991 and 2011 [10], all things equal, it can be inferred that informal settlers con-
stituted roughly 48% of Windhoek population by 2021, of which roughly 40% reside in 
the Havana settlement and other populous settlements such as Babylon, Ombili, 
Okahandja Park, and Goreagab. The population in Havana is largely a working group of 
20–40-year-olds, comprised of unskilled workers, job seekers, and self-employed individ-
uals operating informal businesses [9,10,82]. Thus, electricity consumption is expected to 

Figure 3. Havana informal settlement terrain and characteristics.



Energies 2022, 15, 4235 11 of 32

Although many residents have the means to construct decent housing, houses in the
informal settlements are mainly constructed of cheap and uninsulated corrugated iron that
can easily be erected or removed [10]. This is because most of the informal settlers lack
formal property rights and are therefore at risk of losing their investments in event of evic-
tion from the land. However, the Havana settlement has been proclaimed a city structure
and basic services are gradually being rolled out. This includes electrification of Havana
Ext 1–3 in 2020/2021 through the “Windhoek Peri-Urban Electrification Project” [83–85].
Since service delivery has not kept pace with rapid growth of informal settlements, illegal
electricity connections have been on the rise as the un-electrified residents try to connect
from those legally supplied [86–88].

Available data from 2004 estimated that 29% of the Windhoek population lived in infor-
mal settlements [89]. Since the Windhoek population has grown annually by 4.2% between
1991 and 2011 [10], all things equal, it can be inferred that informal settlers constituted
roughly 48% of Windhoek population by 2021, of which roughly 40% reside in the Havana
settlement and other populous settlements such as Babylon, Ombili, Okahandja Park, and
Goreagab. The population in Havana is largely a working group of 20–40-year-olds, com-
prised of unskilled workers, job seekers, and self-employed individuals operating informal
businesses [9,10,82]. Thus, electricity consumption is expected to be dominated by domestic
consumers and small businesses. The energy needed for cooking and lighting is currently
met by firewood and kerosene, respectively. There are also some users operating diesel
generators, gas cookers, rechargeable portable lamps, and small solar home systems [9].
The characteristics of the site are summed up in Table 3.

Table 3. Site parameters for Havana informal settlement.

Parameter Value

Location name and city: Havana settlement, Windhoek, Namibia
Type of location: Informal settlement (peri-urban area)
Longitude: 22◦29′ S
Latitude: 17◦01′ E
Population: ≈96,000 [10]
Estimated number of dwellings: ≈12,773
Main type of dwellings: Shacks made of corrugated iron [10]

Main source of energy: Electricity (for the electrified area), kerosene, and
firewood (for un-electrified area)

Dominant population: 20–40 years (male and female) [9]

Main source of income: Small informal businesses, general labor, and
construction labor [10]

Monthly income: USD 30–2500 [10]

An aerial and closer view of the Havana settlement is shown in Figure 4. The area
constitutes about 80% residential, 10% small-scale commercial (comprised of small grocery
shops, hair salons, and small liquor shops mainly operated from residential properties),
and the remaining 10% is made up by a few public facilities such as schools, clinics, and
municipal areas. Two sizes of corrugated iron residences are dominant: the 10–12 m2 single
room occupying 1–2 persons and the 15–24 m2 usually partitioned to occupy a family of
2–4 persons, typically a couple with young children. There are also a few brick houses,
mainly 4 rooms structures in the size range of 30–40 m2. These dwellings will henceforth
be referred to as Shack-12sqm, Shack-24sqm, and Brick-House, respectively.



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Energies 2022, 15, x FOR PEER REVIEW 11 of 32 
 

 

be dominated by domestic consumers and small businesses. The energy needed for cook-
ing and lighting is currently met by firewood and kerosene, respectively. There are also 
some users operating diesel generators, gas cookers, rechargeable portable lamps, and 
small solar home systems [9]. The characteristics of the site are summed up in Table 3. 

Table 3. Site parameters for Havana informal settlement. 

Parameter Value 
Location name and city: Havana settlement, Windhoek, Namibia 
Type of location: Informal settlement (peri-urban area) 
Longitude: 22°29′ S 
Latitude: 17°01′ E 
Population: ≈96,000 [10] 
Estimated number of 
dwellings: 

≈12,773 

Main type of dwellings: Shacks made of corrugated iron [10] 

Main source of energy: 
Electricity (for the electrified area), kerosene, and firewood 
(for un-electrified area) 

Dominant population: 20–40 years (male and female) [9] 

Main source of income: Small informal businesses, general labor, and construction la-
bor [10] 

Monthly income: USD 30–2500 [10] 

An aerial and closer view of the Havana settlement is shown in Figure 4. The area 
constitutes about 80% residential, 10% small-scale commercial (comprised of small gro-
cery shops, hair salons, and small liquor shops mainly operated from residential proper-
ties), and the remaining 10% is made up by a few public facilities such as schools, clinics, 
and municipal areas. Two sizes of corrugated iron residences are dominant: the 10–12 m2 
single room occupying 1–2 persons and the 15–24 m2 usually partitioned to occupy a fam-
ily of 2–4 persons, typically a couple with young children. There are also a few brick 
houses, mainly 4 rooms structures in the size range of 30–40 m2. These dwellings will 
henceforth be referred to as Shack-12sqm, Shack-24sqm, and Brick-House, respectively. 

  
(a) (b) 

Figure 4. Different views of Havana informal settlement in Windhoek, Namibia: (a) An aerial view 
of the unstructured portion of the settlement [90]; (b) A closer view of the corrugated iron dwellings 
[91]. 

  

Figure 4. Different views of Havana informal settlement in Windhoek, Namibia: (a) An aerial view of
the unstructured portion of the settlement [90]; (b) A closer view of the corrugated iron dwellings [91].

3.2. Load Assessment

Although extensions 1–3 of Havana settlement have been electrified since 2020 [84],
actual electricity consumption data for the area could not be obtained. The load data
pattern of similar electrified communities in the country are also limited. Therefore, the
“bottom-up” approach [92–94] was used to formulate the daily load profile expected for
the area as outlined in these steps:

1. Determined the surface area of the unelectrified Havana settlement.
2. Estimated the dwellings’ density per 100 m2 from the aerial and satellite imagery in

Google Maps and then extrapolated to determine the total units in the area. A head
count of about 3 dwellings per 100 m2 was observed.

3. Estimated the ratio of residential (80%), commercial (10%), and public institutions
such as schools and clinics (10%). The commercial dwellings are comprised of small
grocery shops and liquor shops, home businesses, and other informal businesses.

4. Divided the residential units into different classes and estimated expected the daily
load. A class ratio of 65% Shack-12sqm, 25% Shack-24sqm, and 10% Brick-House were
assumed. Each residential class was assumed to have the same number and types of
appliances, which were operated at the same time window. The loads for commercial
and public institutions were estimated as different scales of the Brick-House daily load.
Details of the daily profile for Shack-24sqm are shown in Table 4, and the total load
expected for the area in Table 5.

5. Ideal relative load demand curves of domestic and commercial profiles common to
developing countries were assumed. Single-day curves are shown in Figures 5 and 6,
respectively. Relative load demand at any hour Drel,t, is a normalized load (per unit)
defined as the ratio between average hourly demand Dt and peak demand Dp, over a
period of time To.

Drel,t =

(
Dt

Dp

)
for 0 ≤ t ≤ To (1)

6. To make the load profiles more realistic, the daily relative demand profiles were first
scaled by average daily consumption (kWh/day) before randomness was added.
A 20% day-to-day variance and 10% hourly time-step variance were assumed.



Energies 2022, 15, 4235 13 of 32

Table 4. Shack-24sqm daily load profile (a 24 sqm unit segmented into 2 rooms housing a family of 4).

Load Type Power (W) Qty Total Power
(W)

Total Daily
Use (Hours)

Daily
Demand

(kWh/Day)

Living room light 15 1 15 2 0.030
Bedrooms lights 15 2 30 2 0.060
Security light 15 1 15 10 0.150
Single plate cooker 1275 1 1275 0.7 0.893
Fridge (150 lt = 5.3 Cu Ft) 105 1 105 6 0.630
Cell phone charging 9 2 18 1 0.018
Radio 12 1 12 2 0.024
Television (21” LCD) 150 1 150 6 0.900

Average energy demand (kWh/day) 2.705
Average power demand (kW/day) 0.113

Peak demand (kW/day) 0.436

Table 5. Estimated daily load profile for the Havana settlement.

Facility Total Units Unit Demand
(kWh/Day)

Total Daily
Demand

(kWh/Day)

% Daily
Demand

Shack-12 sqm 8303 1.76 14,595.88 38.12%
Shack-24 sqm 3193 2.70 8636.25 22.55%
Brick-House 1277 7.54 9628.40 25.14%
Liquor shops * 102 15.08 1540.54 4.02%
Mini grocery shops 102 16.58 1694.60 4.43%
Small-scale industries 102 20.73 2118.25 5.53%
Public services (e.g.,
schools, clinics, libraries) 3 26.38 79.15 0.21%

Total average energy demand (kWh/day) 38,293.07
Average residential load (kWh/day) 32,860.53
Average community load (kWh/day) 5432.54
Total peak demand (kW/day) 1595.54

* Locally known as shebeens or pubs.

Energies 2022, 15, x FOR PEER REVIEW 13 of 32 
 

 

Table 5. Estimated daily load profile for the Havana settlement. 

Facility Total Units Unit Demand 
(kWh/Day) 

Total Daily Demand 
(kWh/Day) 

% Daily Demand 

Shack-12 sqm 8303 1.76 14,595.88 38.12% 
Shack-24 sqm 3193 2.70 8636.25 22.55% 
Brick-House 1277 7.54 9628.40 25.14% 
Liquor shops * 102 15.08 1540.54 4.02% 
Mini grocery shops 102 16.58 1694.60 4.43% 
Small-scale indus-
tries 102 20.73 2118.25 5.53% 

Public services (e.g., 
schools, clinics, li-
braries) 

3 26.38 79.15 0.21% 

Total average energy demand (kWh/day) 38,293.07 
Average residential load (kWh/day) 32,860.53 
Average community load (kWh/day) 5432.54 

Total peak demand (kW/day) 1595.54 
* Locally known as shebeens or pubs. 

 
Figure 5. Hourly average relative demand for domestic load. Source [60]. 

 
Figure 6. Hourly average relative demand for commercial load. Source [60]. 

Figure 5. Hourly average relative demand for domestic load. Source [60].



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Table 5. Estimated daily load profile for the Havana settlement. 

Facility Total Units Unit Demand 
(kWh/Day) 

Total Daily Demand 
(kWh/Day) 

% Daily Demand 

Shack-12 sqm 8303 1.76 14,595.88 38.12% 
Shack-24 sqm 3193 2.70 8636.25 22.55% 
Brick-House 1277 7.54 9628.40 25.14% 
Liquor shops * 102 15.08 1540.54 4.02% 
Mini grocery shops 102 16.58 1694.60 4.43% 
Small-scale indus-
tries 102 20.73 2118.25 5.53% 

Public services (e.g., 
schools, clinics, li-
braries) 

3 26.38 79.15 0.21% 

Total average energy demand (kWh/day) 38,293.07 
Average residential load (kWh/day) 32,860.53 
Average community load (kWh/day) 5432.54 

Total peak demand (kW/day) 1595.54 
* Locally known as shebeens or pubs. 

 
Figure 5. Hourly average relative demand for domestic load. Source [60]. 

 
Figure 6. Hourly average relative demand for commercial load. Source [60]. Figure 6. Hourly average relative demand for commercial load. Source [60].

In Figure 5, domestic demand is dominated by morning and evening peaks, whereas
commercial demand in Figure 6 is uniformly distributed during the day with a single
evening peak. Commercial loads would be dominated by liquor shops, hair salons, and
other small businesses; while residential needs would mainly be for lighting, television,
radios, phone charging, and refrigeration.

3.3. Renewable Resource Assessment

The study only considers solar and wind resources for the selected site. Both solar and
wind data are obtained from NASA’s (National Aeronautics and Space Administration)
database via HOMER software. The data set is comprised of long-term monthly averages
of global horizontal irradiance recorded over a 22-year period. In Figure 7, the site has
daily average solar radiation of 4.82 kWh/m2 in winter, 7.44 kWh/m2 in summer, and an
annual average of 6.17 kWh/m2. The clearance index is between 0.58 and 0.78 in winter.
Thus, 4 to 7 h of full sunlight is available at the site throughout the year and has potential
to generate adequate electricity from solar photovoltaic (PV) modules.

Energies 2022, 15, x FOR PEER REVIEW 14 of 32 
 

 

In Figure 5, domestic demand is dominated by morning and evening peaks, whereas 
commercial demand in Figure 6 is uniformly distributed during the day with a single 
evening peak. Commercial loads would be dominated by liquor shops, hair salons, and 
other small businesses; while residential needs would mainly be for lighting, television, 
radios, phone charging, and refrigeration. 

3.3. Renewable Resource Assessment 
The study only considers solar and wind resources for the selected site. Both solar 

and wind data are obtained from NASA’s (National Aeronautics and Space Administra-
tion) database via HOMER software. The data set is comprised of long-term monthly av-
erages of global horizontal irradiance recorded over a 22-year period. In Figure 7, the site 
has daily average solar radiation of 4.82 kWh/m2 in winter, 7.44 kWh/m2 in summer, and 
an annual average of 6.17 kWh/m2. The clearance index is between 0.58 and 0.78 in winter. 
Thus, 4 to 7 h of full sunlight is available at the site throughout the year and has potential 
to generate adequate electricity from solar photovoltaic (PV) modules. 

 
Figure 7. Annual solar radiation and clearness index profile for Windhoek. Source [60]. 

Due to wide temperature range of the site (Figure 8), the effect of temperature on solar 
PV modules is considered. Temperature coefficient of −0.41%/°C of power, module efficiency 
of 14.91%, and PV derating factor of 80% are assumed. PV modules are modeled as fixed and 
tilted north at a 45° angle and assumed to use maximum power point tracking (MPPT). 

 
Figure 8. Climate pattern for Windhoek. Source [95]. 

Figure 7. Annual solar radiation and clearness index profile for Windhoek. Source [60].

Due to wide temperature range of the site (Figure 8), the effect of temperature on
solar PV modules is considered. Temperature coefficient of −0.41%/◦C of power, module
efficiency of 14.91%, and PV derating factor of 80% are assumed. PV modules are mod-
eled as fixed and tilted north at a 45◦ angle and assumed to use maximum power point
tracking (MPPT).



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In Figure 5, domestic demand is dominated by morning and evening peaks, whereas 
commercial demand in Figure 6 is uniformly distributed during the day with a single 
evening peak. Commercial loads would be dominated by liquor shops, hair salons, and 
other small businesses; while residential needs would mainly be for lighting, television, 
radios, phone charging, and refrigeration. 

3.3. Renewable Resource Assessment 
The study only considers solar and wind resources for the selected site. Both solar 

and wind data are obtained from NASA’s (National Aeronautics and Space Administra-
tion) database via HOMER software. The data set is comprised of long-term monthly av-
erages of global horizontal irradiance recorded over a 22-year period. In Figure 7, the site 
has daily average solar radiation of 4.82 kWh/m2 in winter, 7.44 kWh/m2 in summer, and 
an annual average of 6.17 kWh/m2. The clearance index is between 0.58 and 0.78 in winter. 
Thus, 4 to 7 h of full sunlight is available at the site throughout the year and has potential 
to generate adequate electricity from solar photovoltaic (PV) modules. 

 
Figure 7. Annual solar radiation and clearness index profile for Windhoek. Source [60]. 

Due to wide temperature range of the site (Figure 8), the effect of temperature on solar 
PV modules is considered. Temperature coefficient of −0.41%/°C of power, module efficiency 
of 14.91%, and PV derating factor of 80% are assumed. PV modules are modeled as fixed and 
tilted north at a 45° angle and assumed to use maximum power point tracking (MPPT). 

 
Figure 8. Climate pattern for Windhoek. Source [95]. Figure 8. Climate pattern for Windhoek. Source [95].

The average wind speed for the site ranged from 4.34 to 6.50 m/s (Figure 9), with an
annual average of 6.31 m/s. This translates between wind power classes 2 and 3, which
can generate marginal to fair wind output.

Energies 2022, 15, x FOR PEER REVIEW 15 of 32 
 

 

The average wind speed for the site ranged from 4.34 to 6.50 m/s (Figure 9), with an 
annual average of 6.31 m/s. This translates between wind power classes 2 and 3, which 
can generate marginal to fair wind output. 

 
Figure 9. Monthly average wind speed for Windhoek. 

3.4. System Component Capacities and Costs 
3.4.1. Solar Photovoltaic Capacity 

The solar photovoltaic output power capacity is a function of the site’s solar radia-
tion, tilt angle, photovoltaic module rating, and temperature. HOMER calculates solar 
photovoltaic array power output as follows [60]: 

( )[ ],

,

1T

PV PV PV P c c STC

T STC

G
P Y f T T

G
α= + −

 
 
  , 

(2)

where 𝑃  is the solar photovoltaic output power, 𝑌  is the rated photovoltaic module 
capacity (kW), 𝑓  is the photovoltaic module derating factor (%), 𝐺  is the photovoltaic 
array incident solar radiation at a given time (kW/m2), 𝐺 ,  is the global incident solar 
radiation (1 kW/m2) under standard test conditions, 𝛼  is the power temperature coeffi-
cient (%/°C), 𝑇  is the temperature of a photovoltaic cell at a given time (°C), and 𝑇 ,  
is the temperature of a photovoltaic cell under standard test conditions (25 °C). 

3.4.2. Wind Capacity 
HOMER computes the wind turbine output power as a 4-steps process [60]. 

1. Generate statistically reasonable hourly time series wind data from monthly average 
wind speeds. This step is only performed when time-series data are not available, as 
with the case in this study. 

2. Calculates the wind speed for the selected wind turbine’s hub height. A generic wind 
turbine of 3 kW rating and 50 m hub height is selected for the study. 

3. Uses the wind turbine power curve to predict the amount of output power that can 
be produced at the wind speed computed in step 2, and at standard air density. 

4. Adjusts the output power in step 3 for the actual air density as follows [60]. 𝑃 = · 𝑃 , , (3)

where 𝑃  is the wind turbine output power in kW, 𝐴  is the actual air density in kg/m3, 𝐴  is the air density at standard conditions (1.225 kg/m3), and 𝑃 ,  is the wind turbine 
output power in kW at standard. 

3.4.3. Diesel Generator, Battery Storage, and Capacity 
Generic HOMER components are used to model the diesel generator, lead acid bat-

teries, and converter. Where applicable, a diesel generator and a battery system are used 

Figure 9. Monthly average wind speed for Windhoek.

3.4. System Component Capacities and Costs
3.4.1. Solar Photovoltaic Capacity

The solar photovoltaic output power capacity is a function of the site’s solar radia-
tion, tilt angle, photovoltaic module rating, and temperature. HOMER calculates solar
photovoltaic array power output as follows [60]:

PPV = YPV fPV

(
GT

GT,STC

)
[1 + αP(Tc − Tc,STC)], (2)

where PPV is the solar photovoltaic output power, YPV is the rated photovoltaic module
capacity (kW), fPV is the photovoltaic module derating factor (%), GT is the photovoltaic
array incident solar radiation at a given time (kW/m2), GT,STC is the global incident solar
radiation (1 kW/m2) under standard test conditions, αP is the power temperature coefficient
(%/◦C), Tc is the temperature of a photovoltaic cell at a given time (◦C), and Tc,STC is the
temperature of a photovoltaic cell under standard test conditions (25 ◦C).

3.4.2. Wind Capacity

HOMER computes the wind turbine output power as a 4-steps process [60].



Energies 2022, 15, 4235 16 of 32

1. Generate statistically reasonable hourly time series wind data from monthly average
wind speeds. This step is only performed when time-series data are not available, as
with the case in this study.

2. Calculates the wind speed for the selected wind turbine’s hub height. A generic wind
turbine of 3 kW rating and 50 m hub height is selected for the study.

3. Uses the wind turbine power curve to predict the amount of output power that can
be produced at the wind speed computed in step 2, and at standard air density.

4. Adjusts the output power in step 3 for the actual air density as follows [60].

PWT =

(
Ai
Ao

)
·PWT,std, (3)

where PWT is the wind turbine output power in kW, Ai is the actual air density in
kg/m3, Ao is the air density at standard conditions (1.225 kg/m3), and PWT,std is the
wind turbine output power in kW at standard.

3.4.3. Diesel Generator, Battery Storage, and Capacity

Generic HOMER components are used to model the diesel generator, lead acid bat-
teries, and converter. Where applicable, a diesel generator and a battery system are used
for backup supply and energy storage, respectively. Output from the diesel generator and
battery system is computed as outlined by Ali et al. [10] and the HOMER manual [60].

3.4.4. Component Costs

In Table 6, a summary of the ratings and costs of system components used in this
study is given.

Table 6. Ratings and costs for various system components used in the study.

Component Product
Specification

Rating
(kW)

Unit Cost
($/Wp)

Capital Cost
(USD) 1

Replacement
Cost (USD) 1

O&M Cost 2

(USD)
Lifetime
(Years)

PV module Generic flat plate 1 0.6 600 540 10 25
Wind turbine Generic 3 3.0 9000 9000 180 20
Converter Generic 1 0.25 250 225 5 15
Deep cycle battery Generic lead Acid 1 kWh 0.49 490 430 10 5
Diesel generator Auto-size Genset N/A 500 N/A 500/kW 0.03/h 15,000 h

1 Component costs are based on quotations sourced from various Namibian suppliers to install a 5 kW solar home
system (SHS). Microgrid components are assumed to be of better quality than an SHS; hence, they are costed
at 20% higher than SHS. Replacement costs for solar PV, batteries, and converters are assumed at 10% less than
capital costs [96–98]. 2 O&M cost for a diesel generator is based on 2021 average fuel price in Namibia [99]. Other
O&M costs are obtained from an IRENA report on African solar PV market [100].

3.5. Techno-Economic Analysis

Energy systems need to be sized properly to ensure accurate matching of supply
and demand and to avoid under- or oversizing of the system that could lead to reduced
reliability or increased costs, respectively. The intermittency behavior of power from
renewable sources and load uncertainties makes it difficult to obtain optimal sizes of
generating units that can cost-effectively meet the load demand. Therefore, use of HOMER
software eases this process by minimizing the difference between generated power and
demanded power over a period of time.

∆P = ∑To
i=0 Pg,i − Pd,i, (4)

where ∆P is the minimal power,
(

Pg,i
)

is the supplied power, (Pd,i) is the demanded power,
and (To) is the simulation time step, usually 60 min.



Energies 2022, 15, 4235 17 of 32

The main economic metrics used in this study to evaluate the economic sustainability
of feasible renewable energy systems are net present costs (NPC), levelized cost of energy
(LCOE), and discounted payback period.

3.5.1. Net Present Cost

The net present cost (NPC) is the present value of all systems costs to be incurred
during its lifetime. It includes costs of capital, component replacements, operation and
maintenance, fuel costs, and salvage. The NPC is calculated by aggregating total and
annual discounted cash flows over the project lifetime. HOMER computes the NPC as
follows [60]:

Cnpc =
Cann,tot

CRF(i, N)
, where CRF =

i(1 + i)N

(1 + i)N − 1
, (5)

where Cnpc is the system net present costs, Cann,total is total costs incurred annually, N is the
interest period (project lifetime), i is the discounted rate, and CRF is the capital recovery
factor, which divides an investment into a stream of equal annual payments over an interest
period N.

3.5.2. Levelized Cost of Energy

Due to opposing cost characteristics between renewable and fossil-fuel-based genera-
tion systems, levelized cost of energy (LCOE) is used to assess the cost-competitiveness
of energy systems. It combines all cost factors into a cost-per-unit measure (USD/kWh).
Thus, LCOE represents the minimum unsubsidized price of energy. HOMER calculates
LCOE as follows [60]:

Ccoe =
Cann,tot

Eprim + Ede f + Egrid,sales
, (6)

where Ccoe is the levelized cost of energy, Cann,tot is the total annualized system costs, Eprim
is the total amount of annual energy used to serve primary load, Ede f is the total amount of
annual energy used to serve deferrable load, Egrid,sales is the total amount of annual energy
sold to the grid per year (if any). Egrid,sales = 0 for off-grid systems.

3.5.3. Discounted Payback Period

Discounted payback period refers to how long it will take (years) to recover the cost of
an initial investment, factoring in the time value of money. Since there is no actual revenue
expected from an off-grid energy system, the cash flow from an investment is defined
as annual savings from not having to pay for the investment or generating power from
an alternative source. For instance, revenue for a renewable solar home system (PV and
battery) can be defined as annual savings from using a diesel-only alternative (base case).
By default, HOMER uses a fossil fuel-based off-grid configuration as the base case and
computes the discounted payback period as follows [60]:

Tdp =
Cost o f investment

Discounted annual savings
= ∑N

n=0

(
In

CFn(1 + r)−n

)
, (7)

where Tdp is the discounted payback period, In is the initial investment in the nth period,
CFn(1 + r)−n is the net discounted cash flow (i.e., discounted annual savings), r is the
discount rate, n is the current year, and N is the project lifetime.

3.5.4. Other Economic Inputs

Apart from the system component costs, this study assumes other economic inputs
listed in Table 7.



Energies 2022, 15, 4235 18 of 32

Table 7. Project economic input assumptions.

Parameter Value

Project lifetime 25 years
Annual discount rate 1 8%
Inflation rate 1 4.5%
Diesel fuel cost 2 USD 1.08/L

1 Discount and inflation rates obtained from [101], 2 Fuel cost obtained from [99].

3.5.5. Potential Energy Configurations

The Potential for solar home systems (SHS) is explored using three off-grid energy
configurations, for each type of dwelling. Scenarios considered are: (i) solar photovoltaic
(PV) and batteries (BAT); (ii) solar photovoltaic and diesel generator (DG); and (iii) solar
photovoltaic, diesel generator, and batteries. Henceforth, the three configurations are
abbreviated as PV|BAT, PV|DG, and PV|DG|BAT.

In addition, the study considers two microgrid scenarios: a rooftop and a ground-
based option. In the first case, solar PV arrays are assumed to be installed on a rooftop
of one of the local schools. This option is valid when a dedicated land for a microgrid
cannot be secured. The four energy configurations considered for SHS are simulated for
a rooftop microgrid. Furthermore, a local school with a total shade-free rooftop area of
2200 m2 (275 m2/building) and a PV module efficiency of 14.9% is simulated. The solar PV
power output is computed as follows [60]:

PPV = APV ·GT,STC·(ηPV), (8)

where PPV is the PV array power output (kW), APV is the rooftop surface area (m2), GT,STC
is the global incident solar radiation (1 kW/m2), and ηPV is the PV module efficiency (%).

The second case considers a ground-based microgrid. In addition to the three off-grid
energy configurations discussed above, a solar photovoltaic (PV), wind turbine (WT), diesel
generator (DG), and batteries (BAT) setup (henceforth, PV|WT|DG|BAT) is simulated.
The HOMER schematic diagrams used to model the SHS for Shack-24sqm load, and a roof-
top microgrid are shown in Figure 10. A load ratio of 75% residential and 25% commercial
load is assumed for a roof-top microgrid to cater to a limited solar PV area.

Energies 2022, 15, x FOR PEER REVIEW 18 of 32 
 

 

m2/building) and a PV module efficiency of 14.9% is simulated. The solar PV power output 
is computed as follows [60]: 𝑃 = 𝐴 · 𝐺 , ·  (𝜂 ), (8)

where 𝑃  is the PV array power output (kW), 𝐴  is the rooftop surface area (m2), 𝐺 ,  is the global incident solar radiation (1 kW/m2), and 𝜂  is the PV module effi-
ciency (%). 

The second case considers a ground-based microgrid. In addition to the three off-grid 
energy configurations discussed above, a solar photovoltaic (PV), wind turbine (WT), die-
sel generator (DG), and batteries (BAT) setup (henceforth, PV|WT|DG|BAT) is simu-
lated. The HOMER schematic diagrams used to model the SHS for Shack-24sqm load, and 
a roof-top microgrid are shown in Figure 10. A load ratio of 75% residential and 25% com-
mercial load is assumed for a roof-top microgrid to cater to a limited solar PV area. 

  
(a) (b) 

Figure 10. A HOMER model for: (a) Shack-24sqm load; (b) Solar rooftop microgrid. 

3.5.6. Energy Dispatching 
HOMER uses two energy dispatching strategies to regulate operations of a diesel 

generator (DG) and charging/discharging of a battery (BAT) storage system to ensure eco-
nomic energy balance between supply and load demand is at each time step. The first 
method, called load following (LF), allows the DG to be operated at its minimum rated 
capacity to serve the net load whenever the output from RES sources is not sufficient. In 
this case, the DG is not used to charge the battery storage, regardless of its state of charge, 
but solely serves the net load [102]. However, when the minimum DG output power is 
more than the net load, the excess DG power is directed to the baseload and RES excess 
power is reserved to charge the BAT. The second technique is the cycle-charging (CC), 
which allows the DG to always be operating at its maximum capacity to serve the net load 
and to use any excess power to charge the battery [102]. Irrespective of the dispatching 
strategy, however, whenever DG and BAT are simultaneously operated, HOMER always 
chooses the most economically available way to serve the load at each time step [103–105], 
as depicted in Figure 11. It can be observed that priority was given to BAT supply in hour 
1–9 to serve the load instead of operating the DG, because BAT seemed economical during 
that time duration. At hour 18–22, and hour 22–24, energy was dispatched from DG and 
BAT, respectively. Although DG and BAT were both available, HOMER had to choose the 
cheapest available energy source at different times. 

Figure 10. A HOMER model for: (a) Shack-24sqm load; (b) Solar rooftop microgrid.

3.5.6. Energy Dispatching

HOMER uses two energy dispatching strategies to regulate operations of a diesel
generator (DG) and charging/discharging of a battery (BAT) storage system to ensure
economic energy balance between supply and load demand is at each time step. The first
method, called load following (LF), allows the DG to be operated at its minimum rated
capacity to serve the net load whenever the output from RES sources is not sufficient. In



Energies 2022, 15, 4235 19 of 32

this case, the DG is not used to charge the battery storage, regardless of its state of charge,
but solely serves the net load [102]. However, when the minimum DG output power is
more than the net load, the excess DG power is directed to the baseload and RES excess
power is reserved to charge the BAT. The second technique is the cycle-charging (CC),
which allows the DG to always be operating at its maximum capacity to serve the net load
and to use any excess power to charge the battery [102]. Irrespective of the dispatching
strategy, however, whenever DG and BAT are simultaneously operated, HOMER always
chooses the most economically available way to serve the load at each time step [103–105],
as depicted in Figure 11. It can be observed that priority was given to BAT supply in
hour 1–9 to serve the load instead of operating the DG, because BAT seemed economical
during that time duration. At hour 18–22, and hour 22–24, energy was dispatched from DG
and BAT, respectively. Although DG and BAT were both available, HOMER had to choose
the cheapest available energy source at different times.

Energies 2022, 15, x FOR PEER REVIEW 19 of 32 
 

 

 
Figure 11. An illustration of how HOMER dispatch energy in a hybrid renewable energy system. 

4. Results and Discussion 
This study explores two potential off-grid electrification methods to supply electric-

ity to the Havana informal settlement in Windhoek, with the aim of finding an optimal 
solution that can cost-effectively meet the load requirements. This section presents and 
discusses simulation results. 

4.1. Electrification through Solar Home Systems (SHS) 
Figure 12 compares the net present costs (NPC) of the three potential energy designs 

for each residential type. Expected daily load demand of 1.76 kWh, 2.71 kWh, and 7.54 
kWh are considered for Shack-12sqm, Shack-24sqm, and BrickHouse-42sqm, respectively. It 
is observed that, for each energy configuration, NPC increases linearly with load demand. 
Costs of fuel and operation and maintenance (O&M) make up the largest share of NPC 
for designs that integrate diesel generators, while capital and replacement costs are the 
highest for a complete renewable option. For instance, in a solar photovoltaic and diesel 
generator (PV|DG) option, fuel and O&M costs together account for between 74% and 
76% of the total cost. In a hybrid solar photovoltaic and batteries (PV|BAT), capital and 
replacement costs respectively account for 82% to 90% of NPC. Thus, a large initial invest-
ment is required to acquire a complete renewable solar home system. 

Figure 11. An illustration of how HOMER dispatch energy in a hybrid renewable energy system.

4. Results and Discussion

This study explores two potential off-grid electrification methods to supply electricity
to the Havana informal settlement in Windhoek, with the aim of finding an optimal solution
that can cost-effectively meet the load requirements. This section presents and discusses
simulation results.

4.1. Electrification through Solar Home Systems (SHS)

Figure 12 compares the net present costs (NPC) of the three potential energy designs for
each residential type. Expected daily load demand of 1.76 kWh, 2.71 kWh, and 7.54 kWh are
considered for Shack-12sqm, Shack-24sqm, and BrickHouse-42sqm, respectively. It is observed
that, for each energy configuration, NPC increases linearly with load demand. Costs of
fuel and operation and maintenance (O&M) make up the largest share of NPC for designs
that integrate diesel generators, while capital and replacement costs are the highest for
a complete renewable option. For instance, in a solar photovoltaic and diesel generator
(PV|DG) option, fuel and O&M costs together account for between 74% and 76% of the total
cost. In a hybrid solar photovoltaic and batteries (PV|BAT), capital and replacement costs
respectively account for 82% to 90% of NPC. Thus, a large initial investment is required to
acquire a complete renewable solar home system.



Energies 2022, 15, 4235 20 of 32Energies 2022, 15, x FOR PEER REVIEW 20 of 32 
 

 

 
Figure 12. Comparing costs of different SHS system configurations. 

In Figure 13, levelized cost of energy (LCOE) for different solar home systems is com-
pared and ranges between USD 0.440/kWh and USD 0.724/kWh for different residential 
loads and energy configurations. The lowest LCOE is from a hybrid solar photovoltaic, 
diesel generator, and batteries (PV|DG|BAT). A lower LCOE is mainly influenced by the 
use of complementary energy sources and system efficiencies. Therefore, a hybrid 
PV|DG|BAT option offers the best economic metrics across all three residential load 
types. Its NPC range of USD 4738 to USD 20,404 is comprised of fuel costs (≈35%), opera-
tion and maintenance costs (≈17%), replacement costs (≈33%), and initial capital (≈16%). 

Although the PV|DG|BAT configuration offers a minimum LCOE of USD 
0.440/kWh, it is almost three times the current grid electricity tariff of USD 0.13/kWh [56] 
and, therefore, not competitive. In addition, it will have unintended consequences such as 
noise and air pollution, stemming from the mass and simultaneous use of diesel genera-
tors by residents. Furthermore, the need to constantly buy fuel and maintain diesel gen-
erators over the system’s lifetime would also deter investment from residents, even when 
the cost of initial investment is subsidized. Therefore, deploying the PV|DG|BAT option 
to each household in this community would not be environmentally responsive. 

Shack-
12sqm

Shack-
24sqm

Brick
House

Shack-
12sqm

Shack-
24sqm

Brick
House

Shack-
12sqm

Shack-
24sqm

Brick
House

PV|DG|BAT PV|DG PV|BAT

Fuel Cost ($) 1609 2344 6630 4475 7081 20,113 0 0 0

O&M Cost ($) 586 919 2510 1207 1828 5202 823 1156 3290

Replacement Cost ($) 1420 2534 6754 1067 1651 4721 3351 5488 13,225

Initial Capital ($) 1136 1881 4984 991 1262 3525 2494 3566 10,066

Daily Load Demand (kWh) 1.76 2.71 7.54 1.76 2.71 7.54 1.76 2.71 7.54

-2
0
2
4
6
8

10
12
14
16
18
20
22
24
26
28
30
32
34

N
et

 P
rs

en
t C

os
ts

  (
U

SD
)

Th
ou

sa
nd

s

NPC of Different Solar Home System (SHS) Configurations 

Figure 12. Comparing costs of different SHS system configurations.

In Figure 13, levelized cost of energy (LCOE) for different solar home systems is com-
pared and ranges between USD 0.440/kWh and USD 0.724/kWh for different residential
loads and energy configurations. The lowest LCOE is from a hybrid solar photovoltaic,
diesel generator, and batteries (PV|DG|BAT). A lower LCOE is mainly influenced by
the use of complementary energy sources and system efficiencies. Therefore, a hybrid
PV|DG|BAT option offers the best economic metrics across all three residential load types.
Its NPC range of USD 4738 to USD 20,404 is comprised of fuel costs (≈35%), operation and
maintenance costs (≈17%), replacement costs (≈33%), and initial capital (≈16%).

Although the PV|DG|BAT configuration offers a minimum LCOE of USD 0.440/kWh,
it is almost three times the current grid electricity tariff of USD 0.13/kWh [56] and, therefore,
not competitive. In addition, it will have unintended consequences such as noise and air
pollution, stemming from the mass and simultaneous use of diesel generators by residents.
Furthermore, the need to constantly buy fuel and maintain diesel generators over the
system’s lifetime would also deter investment from residents, even when the cost of initial
investment is subsidized. Therefore, deploying the PV|DG|BAT option to each household
in this community would not be environmentally responsive.



Energies 2022, 15, 4235 21 of 32Energies 2022, 15, x FOR PEER REVIEW 21 of 32 
 

 

 
Figure 13. Comparing LCOE of different solar home systems. 

4.2. Electrification through Microgrids 
The study compares two microgrid settings: the roof-mounted and ground-mounted. 

A roof-mounted microgrid with a solar PV capacity of 300 kW is designed to supply about 
170 dwellings, comprised of a daily residential load of 2636 kWh and a commercial load 
of 879 kWh. A hybrid solar photovoltaic, diesel generator, and batteries (PV|DG|BAT) is 
the optimal option. The expected NPC, LCOE, and the payback period are USD 8.3 mil-
lion, USD 0.386/kWh, and 3.14 years, respectively. To ensure the reliability of supply, fuel 
and Q&M costs will account for 38% and 15% of NPC, respectively. 

Furthermore, a ground-mounted microgrid is designed to serve the entire un-electri-
fied Havanna settlement, with an estimated residential and commercial average daily 
load of about 5435 kWh and 32,860 kWh, respectively. As shown in Figure 14, the hybrid 
solar photovoltaic, wind turbine, diesel generator, and batteries (PV|WT|DG|BAT) op-
tion offers the lowest NPC and LCOE. However, when compared to the next lowest option 
of hybrid PV|DG|BAT, its NPC and LCOE are only 3% lower, while its initial capital is 
30% higher due to the costs of a wind turbine (WT). Since energy production and energy 
excess between the two models are similar, as noted in Table 8, the PV|DG|BAT option 
would be recommended for the selected site. It offers low capital investment, competitive 
NPC and LCOE, and ease of implementation. The expected NPC, LCOE, and payback 
period from the hybrid PV|DG|BAT are USD 90.8 million, USD 0.388/kWh, and 3.05 
years, respectively. 

PV|BAT PV|DG PV|DG|BAT

Shack-12sqm 0.576 0.713 0.440

Shack-24sqm 0.560 0.709 0.440

Brick-House 0.564 0.724 0.443

0.300
0.320
0.340
0.360
0.380
0.400
0.420
0.440
0.460
0.480
0.500
0.520
0.540
0.560
0.580
0.600
0.620
0.640
0.660
0.680
0.700
0.720
0.740

LC
O

E 
(U

SD
/k

W
h)

L C O E  o f  D i f f e r e n t  S o l a r  H o m e  S y s t e m s  ( S H S )

Figure 13. Comparing LCOE of different solar home systems.

4.2. Electrification through Microgrids

The study compares two microgrid settings: the roof-mounted and ground-mounted.
A roof-mounted microgrid with a solar PV capacity of 300 kW is designed to supply about
170 dwellings, comprised of a daily residential load of 2636 kWh and a commercial load of
879 kWh. A hybrid solar photovoltaic, diesel generator, and batteries (PV|DG|BAT) is the
optimal option. The expected NPC, LCOE, and the payback period are USD 8.3 million,
USD 0.386/kWh, and 3.14 years, respectively. To ensure the reliability of supply, fuel and
Q&M costs will account for 38% and 15% of NPC, respectively.

Furthermore, a ground-mounted microgrid is designed to serve the entire un-electrified
Havanna settlement, with an estimated residential and commercial average daily load of
about 5435 kWh and 32,860 kWh, respectively. As shown in Figure 14, the hybrid solar pho-
tovoltaic, wind turbine, diesel generator, and batteries (PV|WT|DG|BAT) option offers
the lowest NPC and LCOE. However, when compared to the next lowest option of hybrid
PV|DG|BAT, its NPC and LCOE are only 3% lower, while its initial capital is 30% higher
due to the costs of a wind turbine (WT). Since energy production and energy excess between
the two models are similar, as noted in Table 8, the PV|DG|BAT option would be recom-
mended for the selected site. It offers low capital investment, competitive NPC and LCOE,
and ease of implementation. The expected NPC, LCOE, and payback period from the
hybrid PV|DG|BAT are USD 90.8 million, USD 0.388/kWh, and 3.05 years, respectively.



Energies 2022, 15, 4235 22 of 32Energies 2022, 15, x FOR PEER REVIEW 22 of 32 
 

 

 
Figure 14. Comparing costs of different microgrid system configurations. 

Table 8. Techno-economic comparison of different energy system configurations *. 

Load Configuration Capacity 1 DS 2 EP 3 

MWh/Year 
REP 4 

% 
EE 5 

% 

NPC 6 

USD 
Thsd 13 

CAP 7 

USD 
Thsd 13 

LCOE 8 

US$/kWh 
DPP 9 
Years 

Sh
ac

k-
24

sq
m

 PV|BAT 
1.68 kW|5 kWh|0.437 

kW 
CC 10 3.25 12 100.0 63.6 9.27 3.57 0.560 - 

PV|DG 
1.63 kW|0.49 kW|0.168 

kW 
CC 4.08 12 77.2 75.4 11.76 1.26 0.709 5.20 

PV|DG|BAT 
0.98 kW|0.49 kW|2 

kWh|0.27 kW 
LF 11 2.26 12 84.0 52.2 7.29 1.88 0.440 2.85 

M
ic

ro
gr

id
-R

oo
f 

PV|BAT 
2.41 MW|5.74 MWh|0.56 

MW 
CC 4.68 100.0 67.4 13,587 5295 0.633 - 

PV|DG 
1.87 MW|0.59 MW|0.21 

MW 
CC 4.79 75.7 72.8 12,110 1703 0.563 7.09 

PV|DG|BAT 
1.06 kW|0.59 MW|1.25 

MWh|0.32 MW 
LF 2.66 76.9 49.2 8297 1889 0.386 3.14 

M
ic

ro
gr

id
-G

ro
un

d 

PV|BAT 
26.61 MW|63,424 

kWh|6508 kW 
CC 51.63 100.0 67.7 150,825 58,532 0.644 - 

PV|DG 
19.55 MW|6.60 MW|2.24 

MW 
CC 50.94 74.5 72.2 131,984 18,045 0.564 6.74 

PV|DG|BAT 
11.52 MW|6.60 

MW|12.18 MWh|3.53 
MW 

LF 29.37 76.1 49.9 90,834 19,840 0.388 3.05 

PV|WT|BAT 
17.77 MW|1.40 

MW|61.64 MWh|6.06 
MW 

CC 42.49 100.0 62.6 135,440 63,577 0.579 5.17 

PV|WT|DG 
19.42 MW|—|6.60 

MW|2.19 MW 
CC 50.71 74.3 72.0 131,933 17,940 0.563 6.69 

PV|BAT PV|DG
PV|DG
|BAT

PV|BAT PV|DG
PV|DG
|BAT

PV|WT
|BAT

PV|WT
|DG

PV|WT
|DG|B

AT

Roof-mounted Microgrid Ground-mounted Microgrid

Salvage ($) −942,072 −38,332 −371,237 −9,978,032 −421,407 −2,759,154 −14,420,57 −407,510 −3,543,987

Fuel Cost ($) − 6,179,600 3,131,580 − 66,897,27 34,787,47 − 66,946,42 27,611,07

O&M Cost ($) 1,413,812 2,246,583 1,207,990 15,629,87 24,899,18 13,445,73 18,033,57 24,890,74 14,067,63

Replacement Cost ($) 7,820,189 2,018,867 2,439,873 86,641,40 22,564,45 25,520,23 68,250,63 22,563,22 24,236,28

Initial Capital ($) 5,294,983 1,702,839 1,889,008 58,531,84 18,044,64 19,839,82 63,576,86 17,939,90 25,850,81

−20 
− 

 20
 40
 60
 80

 100
 120
 140
 160
 180

N
et

 P
re

st
nt

 C
os

t  
(U

SD
)

M
ill

io
ns

Comparing NPC of Different Microgrid Configurations 

Figure 14. Comparing costs of different microgrid system configurations.

4.3. Comparing Electrical Productions

A comparison of the LCOE of various feasible configurations is shown in Figure 15.
The lowest LCOE of USD 0.377/kWh, is from a hybrid PV|WT|DG|BAT ground-mounted
microgrid. Apart from system component costs, the use of complementary power sources
and the energy dispatching technique can result in a lower LCOE. For instance, combining
solar PV with wind, and dispatchable power sources, such as DG and/or BAT, can offset
the limitations of each power source by minimizing initial capital and fuel costs.

Moreover, excess electricity observed in Table 8 is mainly due to non-dispatchable
renewable sources, which do not always produce power at the time of need. There-
fore, it needs to be controlled to maintain system frequency and bus voltages. Use of
dump/resistive load in the form of a water heater or air cooler, and demand response, are
common control techniques for off-grid solutions. In the case of the Havana settlement, a
separate battery charging station can be considered as a dump load, which allows residents
to charge their rechargeable equipment at a fee to offset this investment. With demand
response, consumers are encouraged to operate certain loads at specific times for less tariff,
thus reducing the need to operate a diesel generator to serve at peak load.

4.4. Sensitivity Analysis

A sensitivity analysis is performed on the PV|WT|DG|BAT ground-based microgrid
to assess the impact of change in fuel price, load growth, and solar PV installed cost on
NPC, LCOE, initial capital, and system capacity.



Energies 2022, 15, 4235 23 of 32

Table 8. Techno-economic comparison of different energy system configurations *.

Load Configuration Capacity 1 DS 2 EP 3

MWh/Year
REP 4

%
EE 5

%

NPC 6

USD
Thsd 13

CAP 7

USD
Thsd 13

LCOE 8

US$/kWh
DPP 9

Years

Sh
ac

k-
24

sq
m

PV|BAT 1.68 kW|5 kWh|
0.437 kW CC 10 3.25 12 100.0 63.6 9.27 3.57 0.560 -

PV|DG 1.63 kW|0.49 kW|
0.168 kW CC 4.08 12 77.2 75.4 11.76 1.26 0.709 5.20

PV|DG|BAT 0.98 kW|0.49 kW|
2 kWh|0.27 kW LF 11 2.26 12 84.0 52.2 7.29 1.88 0.440 2.85

M
ic

ro
gr

id
-R

oo
f PV|BAT 2.41 MW|

5.74 MWh|0.56 MW CC 4.68 100.0 67.4 13,587 5295 0.633 -

PV|DG 1.87 MW|0.59 MW|
0.21 MW CC 4.79 75.7 72.8 12,110 1703 0.563 7.09

PV|DG|BAT 1.06 kW|0.59 MW|
1.25 MWh|0.32 MW LF 2.66 76.9 49.2 8297 1889 0.386 3.14

M
ic

ro
gr

id
-G

ro
un

d

PV|BAT 26.61 MW|
63,424 kWh| 6508 kW CC 51.63 100.0 67.7 150,825 58,532 0.644 -

PV|DG 19.55 MW|
6.60 MW|2.24 MW CC 50.94 74.5 72.2 131,984 18,045 0.564 6.74

PV|DG|BAT 11.52 MW|6.60 MW|
12.18 MWh|3.53 MW LF 29.37 76.1 49.9 90,834 19,840 0.388 3.05

PV|WT|BAT 17.77 MW|1.40 MW|
61.64 MWh|6.06 MW CC 42.49 100.0 62.6 135,440 63,577 0.579 5.17

PV|WT|DG 19.42 MW|—|
6.60 MW|2.19 MW CC 50.71 74.3 72.0 131,933 17,940 0.563 6.69

PV|WT|DG|BAT
8.87 MW|0.87 MW|

6.60 MW|12.55 MWh|
3.19 MW

LF 27.69 80.0 47.4 88,222 25,851 0.377 3.65

* Abbreviations used in this table are listed below: 1 Capacities for Solar PV|Wind|Diesel|Battery|Converter
(whichever is applicable). 2 DS—Dispatching Strategy, 3 EP—Energy Production (kWh/yr), 4 REP—Renewable
Energy Production, 5 EE—Excess Energy, 6 NPC—Net Present Cost, 7 CAP—Initial Capital Cost, 8 LCOE—
Levelized Cost of Energy, 9 DPP—Discounted Payback Period, 10 CC—Cycle Charging, 11 LF—Load Following,
12 These values are kilowatts (KW), 13 Thsd—Amount in thousand US dollars.

4.4.1. Fuel Price Variations

From February 2018 to February 2022, the highest fuel price increase recorded in
Windhoek was 7.64% and the lowest price decrease was 2.2% [99]. Therefore, the diesel
fuel price is varied between the two limits. A base diesel price of USD 1.08/L, recorded
in February 2022, is used. Figure 16 shows that an increase in the diesel price by 7.64%
increases all system costs, except capital costs, owing to reduced diesel generator capacity
(as a means to save costs). A fuel price reduction of 2.2% decreases system costs, except for
operating costs. This is due to the frequent use of the diesel generator to serve the net load.
In each case, however, solar PV and wind capacity are reduced to maintain lower marginal
costs. This implies that the diesel generator has to run longer to make up for the reduced
renewable supply.

4.4.2. Load Variations

A load increase of 30% and 100% is simulated. The choice of 30% growth aligns with
the expected annual growth of informal settlements in Namibia [10]. From Figure 17, system
costs and component capacities increased to cater for load growth, with few exceptions.
For instance, LCOE decreases with load growth because generated energy is efficiently
put to use. Renewable energy systems tend to be oversized to increase reliability, thus
resulting in large excess energy, which is mostly wasted in an off-grid system. When the
load increases, existing excess energy is consumed, and generation capacity only needs



Energies 2022, 15, 4235 24 of 32

to increase marginally to cater for load growth. With less unused energy, the cost of
energy reduces.

Energies 2022, 15, x FOR PEER REVIEW 23 of 32 
 

 

PV|WT|DG|BAT
8.87 MW|0.87 MW|6.60 
MW|12.55 MWh|3.19 

MW 
LF 27.69 80.0 47.4 88,222 25,851 0.377 3.65 

* Abbreviations used in this table are listed below: 1 Capacities for Solar PV|Wind|Diesel|Bat-
tery|Converter (whichever is applicable). 2 DS—Dispatching Strategy, 3 EP—Energy Production 
(kWh/yr), 4 REP—Renewable Energy Production, 5 EE—Excess Energy, 6 NPC—Net Present Cost, 7 
CAP—Initial Capital Cost, 8 LCOE—Levelized Cost of Energy, 9 DPP—Discounted Payback Period, 
10 CC—Cycle Charging, 11 LF—Load Following, 12 These values are kilowatts (KW), 13 Thsd—Amount 
in thousand US dollars. 

4.3. Comparing Electrical Productions 
A comparison of the LCOE of various feasible configurations is shown in Figure 15. 

The lowest LCOE of USD 0.377/kWh, is from a hybrid PV|WT|DG|BAT ground-mounted 
microgrid. Apart from system component costs, the use of complementary power sources 
and the energy dispatching technique can result in a lower LCOE. For instance, combining 
solar PV with wind, and dispatchable power sources, such as DG and/or BAT, can offset 
the limitations of each power source by minimizing initial capital and fuel costs. 

 
Figure 15. Comparing LCOE of different electrification schemes. 

Moreover, excess electricity observed in Table 8 is mainly due to non-dispatchable 
renewable sources, which do not always produce power at the time of need. Therefore, it 
needs to be controlled to maintain system frequency and bus voltages. Use of dump/re-
sistive load in the form of a water heater or air cooler, and demand response, are common 
control techniques for off-grid solutions. In the case of the Havana settlement, a separate 
battery charging station can be considered as a dump load, which allows residents to 
charge their rechargeable equipment at a fee to offset this investment. With demand re-
sponse, consumers are encouraged to operate certain loads at specific times for less tariff, 
thus reducing the need to operate a diesel generator to serve at peak load. 

  

PV|BAT PV|DG
PV|DG|

BAT
PV|WT|

BAT
PV|WT|

DG
PV|WT|
DG|BAT

Shack-12sqm 0.576 0.713 0.440

Shack-24sqm 0.560 0.709 0.440

BrickHouse 0.564 0.724 0.443

Roof Microgrid 0.633 0.563 0.386

Ground Microgrid 0.644 0.564 0.388 0.579 0.563 0.377

0.300

0.350

0.400

0.450

0.500

0.550

0.600

0.650

0.700

0.750

0.800

LC
O

E 
(U

SD
/k

W
h)

LCOE of  Different  System Configurat ions

Figure 15. Comparing LCOE of different electrification schemes.

Energies 2022, 15, x FOR PEER REVIEW 24 of 32 
 

 

4.4. Sensitivity Analysis 
A sensitivity analysis is performed on the PV|WT|DG|BAT ground-based microgrid 

to assess the impact of change in fuel price, load growth, and solar PV installed cost on 
NPC, LCOE, initial capital, and system capacity. 

4.4.1. Fuel Price Variations 
From February 2018 to February 2022, the highest fuel price increase recorded in 

Windhoek was 7.64% and the lowest price decrease was 2.2% [99]. Therefore, the diesel 
fuel price is varied between the two limits. A base diesel price of USD 1.08/L, recorded in 
February 2022, is used. Figure 16 shows that an increase in the diesel price by 7.64% in-
creases all system costs, except capital costs, owing to reduced diesel generator capacity 
(as a means to save costs). A fuel price reduction of 2.2% decreases system costs, except 
for operating costs. This is due to the frequent use of the diesel generator to serve the net 
load. In each case, however, solar PV and wind capacity are reduced to maintain lower 
marginal costs. This implies that the diesel generator has to run longer to make up for the 
reduced renewable supply. 

 
Figure 16. Impact of fuel price change on system costs. 

4.4.2. Load Variations 
A load increase of 30% and 100% is simulated. The choice of 30% growth aligns with 

the expected annual growth of informal settlements in Namibia [10]. From Figure 17, sys-
tem costs and component capacities increased to cater for load growth, with few excep-
tions. For instance, LCOE decreases with load growth because generated energy is effi-
ciently put to use. Renewable energy systems tend to be oversized to increase reliability, 
thus resulting in large excess energy, which is mostly wasted in an off-grid system. When 
the load increases, existing excess energy is consumed, and generation capacity only 
needs to increase marginally to cater for load growth. With less unused energy, the cost 
of energy reduces. 

 
Figure 17. Impact of load growth on system costs. 

Figure 16. Impact of fuel price change on system costs.

Energies 2022, 15, x FOR PEER REVIEW 24 of 32 
 

 

4.4. Sensitivity Analysis 
A sensitivity analysis is performed on the PV|WT|DG|BAT ground-based microgrid 

to assess the impact of change in fuel price, load growth, and solar PV installed cost on 
NPC, LCOE, initial capital, and system capacity. 

4.4.1. Fuel Price Variations 
From February 2018 to February 2022, the highest fuel price increase recorded in 

Windhoek was 7.64% and the lowest price decrease was 2.2% [99]. Therefore, the diesel 
fuel price is varied between the two limits. A base diesel price of USD 1.08/L, recorded in 
February 2022, is used. Figure 16 shows that an increase in the diesel price by 7.64% in-
creases all system costs, except capital costs, owing to reduced diesel generator capacity 
(as a means to save costs). A fuel price reduction of 2.2% decreases system costs, except 
for operating costs. This is due to the frequent use of the diesel generator to serve the net 
load. In each case, however, solar PV and wind capacity are reduced to maintain lower 
marginal costs. This implies that the diesel generator has to run longer to make up for the 
reduced renewable supply. 

 
Figure 16. Impact of fuel price change on system costs. 

4.4.2. Load Variations 
A load increase of 30% and 100% is simulated. The choice of 30% growth aligns with 

the expected annual growth of informal settlements in Namibia [10]. From Figure 17, sys-
tem costs and component capacities increased to cater for load growth, with few excep-
tions. For instance, LCOE decreases with load growth because generated energy is effi-
ciently put to use. Renewable energy systems tend to be oversized to increase reliability, 
thus resulting in large excess energy, which is mostly wasted in an off-grid system. When 
the load increases, existing excess energy is consumed, and generation capacity only 
needs to increase marginally to cater for load growth. With less unused energy, the cost 
of energy reduces. 

 
Figure 17. Impact of load growth on system costs. Figure 17. Impact of load growth on system costs.



Energies 2022, 15, 4235 25 of 32

4.4.3. PV Installed Costs Variations

As noted earlier, global solar PV module costs have declined in the past decade. For
instance, between 2019 and 2020, the global annual cost of crystalline modules declined
between 5% and 15% [28]. The southern African market has also witnessed an average
annual decline of 7% between 2013 and 2020 [100]. Thus, solar PV module decreases of
5%, 7%, and 15% are considered as sensitivity values. Figure 18 shows that decreasing the
solar PV module price by up to 15% does not yield a significant decrease in system costs,
except for the LCOE. This is because wind energy and diesel generators are available for
this model as alternative power sources to economically satisfy load demand.

Energies 2022, 15, x FOR PEER REVIEW 25 of 32 
 

 

4.4.3. PV Installed Costs Variations 
As noted earlier, global solar PV module costs have declined in the past decade. For 

instance, between 2019 and 2020, the global annual cost of crystalline modules declined 
between 5% and 15% [28]. The southern African market has also witnessed an average 
annual decline of 7% between 2013 and 2020 [100]. Thus, solar PV module decreases of 
5%, 7%, and 15% are considered as sensitivity values. Figure 18 shows that decreasing the 
solar PV module price by up to 15% does not yield a significant decrease in system costs, 
except for the LCOE. This is because wind energy and diesel generators are available for 
this model as alternative power sources to economically satisfy load demand. 

 
Figure 18. Impact of PV module price decrease on system costs for the PV|WT|DG|BAT model. 

4.5. Specific Implementation Considerations for the Selected Study Area 
The Namibian energy sector adopted several policies to increase renewable share and 

to promote energy infrastructure investment. These include the National Energy Policy, 
National Electrification Policy, Independent Power Producer, Renewable Energy Policy, 
Off-grid Electrification Policy, and Modified Single Buyer market framework. Conse-
quently, the renewable energy market has grown in the past five years [50,51]. Useful to 
the case study is the solar revolving fund (SRF) scheme that provides loans at subsidized 
interest rates to end users that install either a solar home system, solar water heating, or 
solar water pump