Modeling, design and optimization of integrated renewable energy systems for electrification in remote communities

Integrated renewable energy systems are becoming a promising option for electrification in remote communities. Integrating multiple renewable energy sources allows the communities to counteract the weaknesses of one renewable energy source with the strengths of another. This study aims to model, design and optimize integrated renewable energy systems consisting of solar photovoltaic (PV) panels, wind turbines, a biomass power generator, and storage batteries for applications in remote communities in Canada. Biomass is used as a fuel to produce electricity during periods when solar power and wind power are not capable of meeting the power demand. A methodology is developed to optimize the integrated renewable energy systems design, with the aim of minimizing the net present cost (NPC) and the levelized cost of electricity (LCOE) of the energy systems. Results show that the NPC is $3.61 M and the LCOE is $0.255/kWh for an optimized integrated renewable energy system in a sample remote community that has a peak power consumption of 238.7 kW and an average load demand of 2230 kWh/day. Through the present research, the integrated energy systems are evidenced to be an effective option for electrification in remote communities.

There are several factors that have attracted significant attention to renewable energy applications. The factors include advancing renewable energy technologies, growing environment concerns, and interest towards energy sustainability and security. Although renewable energy utilization is important to sustainable development, certain issues such as the intermittent nature of solar and wind generation and production costs are to be considered in the design and application of the renewable energy systems. The intermittency issue can be overcome by using integrated renewable energy systems where two or more types of renewable energy sources are integrated. In other words, combining multiple renewable energy sources including solar, wind and biomass can offset each other’s weaknesses. The costs of electricity production could be reduced by optimizing the integrated energy systems according to geographical places. Hence, the optimization of integrated renewable energy systems is a research field with important areas worthy to be investigated (Bahramara et al., 2016; Prabatha et al., 2020). Suitable methodologies can provide simulation support tools for system sizing at the project design stages and evaluation of trade-offs among various system configurations (Kamaril et al., 2020; Thirunavukkarasu et al., 2023). For instance, economic sizing of an integrated renewable energy system for stand-alone usage was analyzed by Hosseinalizadeh et. al. (2016). They simulated the performance of various renewable energy system configurations incorporating solar photovoltaic (PV) cells, wind turbine and fuel cell (FC) for use in Iran. Bagheri et. al. (2018) examined optimal planning of integrated renewable energy infrastructure for urban sustainability and assessed the impact of the economics of scale on the life-cycle costs of hybrid renewable systems for Vancouver, Canada. Akinyele and Rayudu (2016) conducted techno-economic and environmental analyses of a solar PV microgrid for remote communities in a small village. Shahzad et. al. (2017) proposed an optimal economic plan for electricity generation using an integrated renewable energy system, including solar panels and biomass on an agricultural field and a residential community in Pakistan. Shezan et. al. (2016) examined an off-grid integrated energy system consisting of solar PV, wind turbine, diesel power and batteries for a small community in Malaysia with an average load demand of 33 kWh/day and a peak load of 3.9 kW to reduce dependence on fossil fuels. Their research showed that the net present cost (NPC) of the designed integrated energy system was 29.7% less than the NPC of the conventional power plant. Baneshi and Hadianfard (2016) investigated the viability of generating electricity from an energy system including batteries, diesel generator, solar cells and wind turbine, noting that adding battery component to the stand-alone integrated energy system improved overall system efficiency.

The process of selecting a proper integrated energy system could be a complex task. Sedghiyan et. al. (2021) noted that the most suitable renewable energy sources in Iran were solar and then wind energy. In fact, solar and wind power production technologies are used in many countries due to their maturity, high social acceptance, and widespread use (Almutairi et al., 2021). However, the use of a single renewable energy source such as wind or solar energy to supply electricity has low reliability due to the availability of these sources being intermittent or random and dependent on weather conditions (Sameti et al., 2014). Therefore, combining renewable sources to form an integrated energy system is an effective solution to overcoming the weaknesses of a single renewable energy source (Sinha et al., 2014). Singh et. al. (2016) carried out a feasibility study of a renewable energy based microgrid in rural area and used a swarm based artificial bee colony algorithm to optimize the sizing of system components. Comparably, Diab et. al. (2020) studied optimal sizing of hybrid solar/wind/hydroelectric pumped storage energy system in Egypt based on different metaheuristic techniques. They investigated the implementation of different optimization techniques to achieve optimal sizing of grid-connected hybrid renewable energy systems. Also, Rahbar et. al. (2018) studied energy cooperation optimization in microgrids with renewable energy integration and the impacts of microgrids’ energy cooperation and energy storage on electricity cost. Bartolini et. al. (2020) investigated multi-energy systems with energy storage for local communities and evaluated the optimal portfolio of energy conversion and lithium-ion battery electricity storage, but they did not disclose the cost of the battery. More recently, Afif et al. (2023) have carried out a feasibility and optimal sizing analysis of hybrid renewable energy systems. In their case study, grid-connected and stand-alone renewable energy systems consist of a wind turbine, a biogas power plant, solar PV panels, flywheels, and batteries. They claimed that a cost of electricity of $0.049 kWh could be achieved by the hybrid energy systems.

Mahbaz et. al. (2020) evaluated the needs and requirements for the provision of critical energy services to communities in Canada’s northern regions. They proposed enhanced geothermal system concepts as part of integrated solutions over the long term and conducted a technical and economic feasibility study of the integration of different local energy sources (renewable and non-renewable) to establish a pathway for low-carbon and sustainable energy supply. Moreover, Das and Cañizares (2019) examined renewable energy integration in diesel-based microgrids in Canada’s remote arctic communities where the dependence on diesel and its associated costs are an economic issue and found that the optimal plan was diesel–renewable hybrid combinations. In parallel, Holdmann et. al. (2019) analyzed economic drivers and technical strategies for renewable energy integration in Alaska’s remote islanded microgrids and pointed out that the primary technical hurdles for renewable energy integration included management of distributed energy resources and reliable design for resilient operation. Holdmann et. al. (2022) discussed pathways to renewable energy transitions in remote Alaska communities where climate conditions are more or less similar to communities in Northern Canada. These researchers conducted a comparative analysis of 24 remote communities in Alaska to identify the factors that could lead to implementing renewable energy technologies and showed that three most important primary factors were community capacity to manage projects and infrastructure, electricity subsidies, and pooled resources. McCallum et. al. (2021) examined renewable electricity generation for off-grid remote communities in Alaska and compared the renewable electricity generation with the existing diesel electricity generation based on a life-cycle assessment. Their comparative results showed that the transition from diesel electricity generation could reduce the carbon intensity of energy generation from 1345.46 to 175.56 kg CO₂/MWh. Recently, Sambor et. al. (2023) have analyzed and optimized a 25-kW microgrid system consisting of solar PV panels, batteries and a diesel power generator in Yukon, Canada, to determine how to best operate the diesel generator to maximize solar PV generation, thus minimizing diesel cost. They reported that solar PV with batteries could meet 96% of load during June, but only 3% during December, and 67% year-round. However, no information on battery cost was provided in their paper. Also, Stringer and Joanis (2023) have used an integer optimization model to analyze the least costly decarbonization solution for Canada’s remote microgrids from now until 2050. Their analysis results show that the cost of decarbonizing Canada’s remote microgrids is not prohibitive. Wind turbines appeared to be the cheapest option for many examined off-grid communities in 2020, whereas solar PV would be the cheapest option in the future. They have noted that communities that currently use diesel to produce electricity should consider undergoing decarbonization as soon as possible.

Canada has approximately ten million square-kilometers of land, and expanding the electrical grid to every corner of the country is not financially feasible. As a result, there are more than 300 communities including many remote aboriginal ones across Canada where people live off-grid (Government of Canada, 2011). In these communities, fossil fuel-based generators are a commonly adopted source of electricity generation, resulting in adverse environmental impacts. Investigations of optimized integrated renewable energy systems at community-scale, are therefore required, especially under the conditions of Canada’s remote northern communities, most of which are dependent on diesel power.

The main objective of this study is to model, design and optimize integrated renewable energy systems for remote community applications in Canada, with the aim of replacing diesel power in the areas where diesel fuel is being used for electricity production. This paper presents a methodology for designing, optimizing, and ranking the integrated energy systems. The optimized system configuration can minimize the NPC as well as the levelized cost of electricity (LCOE). The optimization is performed using the HOMER software (HOMER Energy, 2023).

Description

The design of integrated renewable energy systems involves modular arrangement for solar PV and wind turbine units to obtain the required capacity by increasing or decreasing the number of solar PV panels and wind turbines. The system size is optimized through determination of the number of solar PV panels and wind turbines. The biomass to power module consists of a biomass gasifier and an internal combustion engine (ICE) generator. The integrated renewable energy systems are designed by prioritizing solar and wind power subsystems over the biomass to power subsystem. The integrated system power capacity is determined using the established model based on the average value of hourly power demand of the selected community.

System components

Solar PV panel

Solar PV is widely used to produce electric power from sunlight. The power output of PV panels is affected by various parameters such as solar irradiation, cell efficiency, daytime ambient temperature, etc. In practice, the solar PV performance depends on the cell technology, geographical location, tilt angle and dust accumulation on the solar PV panels. The power output of a solar PV panel is calculated from (Almutairi et al., 2021; Jahangiri et al., 2019):

where P₀ is the nominal power of the solar PV panel, f_PV is the derating factor relative to the losses due to soiling on the panel and the ambient temperature effect, I_T is the incident radiation (kW/m²), I_S is the incident radiation on the cell surface under standard conditions (1 kW/m²), α is the temperature coefficient, T_C is the cell temperature under operating conditions, and T_S is the temperature of cells under standard test conditions. There are different models for solar PV power generation, resulting in different calculation formulae (Hoff & Perez, 2010). Equation (1) was derived and used by many researchers (Dolara et al., 2015; IEC, 2021).

Figure 1 shows the daily horizontal radiation and clearness index over a year at the study location that is in Canada’s Inuvik region (NASA, 2017). The clearness index is a measure of the clearness of the atmosphere and is defined as the surface radiation divided by the extraterrestrial radiation.

Daily horizontal radiation and clearness index for 12 months at the study location

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Wind turbine

The amount of air entering and exiting a turbine is unchanged due to the mass conservation of the air stream. Based on Betz’s law (Hansen, 2007), the maximal achievable extraction of wind power by a wind turbine equals 16/27% of the kinetic energy of the air that reaches the effective disk area of the turbine equipment. Here, it is noted that Betz’ law is a theory about the maximum possible energy to be derived from a wind turbine. It was developed in 1919 by German physicist Albert Betz. According to the rule, no turbine can capture more than 59.3 (16/27) % of the potential energy in wind. Thus, the maximum power output, P_wm of a turbine is given by (Solomon et al., 2023):

where A is the effective area of the disk, v is the wind velocity, and ρ is the air density. The rated power of the wind turbine is obtained from:

where C_wp is the power coefficient provided by a manufacturer. In addition, the power output of the wind turbine varies with the hub height. At a given hub height H, the wind velocity is calculated from (Baghaee et al., 2016):

where v_ref is the reference velocity measured at the reference hub height, H_ref is the reference hub height and γ is the power law exponent or Hellmann exponent (Tar, 2008). It is in range of 0.10 to 0.25. A power law exponent value of 0.15 is used in the present work. Figure 2 shows the monthly average wind velocities at a reference hub height of 10 m at the study location, with the annual average being 5.3 m/s (NASA, 2017). A wind turbine with rated 10 kW capacity is chosen for the present case study.

Monthly average wind velocities at a reference hub height of 10 m at the study location

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Biomass power

Biomass to power is achieved using a biomass gasifier together with an ICE generator. Biomass gasification comprises an incomplete biomass combustion process at high temperatures, resulting in the production of combustible gases. The produced biogas can have a lower heating value (LHV) of approximate 5.5 MJ/kg (Bagheri et al., 2018; Couto et al., 2013) and be used as a fuel in ICE or more efficient gas turbines. Note that 1 kg of wood biomass can produce 2.4 kg of biogas from the gasification. The LHV of the biomass is relatively low due to high CO₂ and N₂ content (Couto et al., 2013). In this study, the biogas LHV calculated using HOMER is 5.5 MJ/kg as well. The net power output from a biogas-fired generator is expressed as (Bagheri et al., 2018):

where P_{bio_tot} is the total electrical output, P_aux is the power needed for auxiliary components, η_bioel is the electric conversion efficiency, G_LHV is the lower heating value of biogas, and V_bio is the volumetric flow rate of biogas.

Batteries

In integrated energy systems, the incorporation of batteries increases system reliability (Bagheri et al., 2018). The batteries serve as energy storage medium, store surplus renewable energy, and supply the energy during capacity shortage. At present, the estimated cost for the suggested lithium-ion batteries is $550/kWh for remote community applications (HOMER Energy, 2023). The simulations are performed in increments of 100 kWh for battery energy storage capacity, in accordance with the chosen battery size per pack. It is known that lithium-ion battery price has decreased significantly over the past decade and the price is expected to decrease further as the battery technology progresses. The integrated renewable energy systems are proposed and designed for the remote northwestern communities in Canada where expensive and carbon-intensive diesel power is consumed. Table 1 shows the capital, replacement, and O&M costs for solar PV, wind turbine, biomass to power and battery components, and associated technical characteristics.

Economic assessment

LCOE and NPC are considered the most relevant economic indicators and the achievement of their minimum values defines an optimal energy system. The real interest rate is calculated from (Dehshiri, 2022):

where i' is the nominal interest rate and f is the rate of annual inflation. NPC is calculated from:

where C_atot is the total annualized cost, CRF is the capital recovery factor and N is the project lifetime. CRF is given by:

LCOE, i.e., the price of each kilowatt hour of electricity generated, is calculated from (Branker et al., 2011):

where E_load is the total electrical load served annually (kWh/year). LCOE is used to evaluate the economic competitiveness of electricity generation technologies over the long term (Branker et al., 2011).

The proposed integrated renewable systems consist of solar PV, wind turbine, biomass-based generator, and electricity storage unit. The biomass-based generator supplies power on demand when solar PV and wind turbine are not capable of meeting required power demand. HOMER is used to simulate the integrated power systems performance and optimize integrated system configurations. The HOMER built-in algorithm performs calculations of hourly power balance for pre-defined integrated scenarios subject to meeting multi-criteria and constraints. It uses the load demand profile, the resources, the component specifications, the constraints, and the emission data as inputs to simulate various feasible configurations and rank them. Table 2 lists the constraints used in the optimization process.

Figure 3 shows the model schematic of the integrated renewable energy system. The components of the integrated energy system include solar PV, wind turbine, biomass-based generator, battery, and converter (HOMER Energy, 2023). Figure 4 illustrates the flow diagram of the modeling and optimization procedure used in this study. Specifically, economic data, load data, technical data, environmental data such as equivalent CO₂ emission factors of the components and hourly time step are used to seek optimal system configurations.

Schematic of the proposed integrated renewable energy system

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HOMER simulation and optimization procedure

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The objective functions in the optimization are based on minimum NPC and LCOE. NPC of a power system is defined as the system’s present value costs over the system lifetime minus the net present value of all the revenues that it earns over the system lifetime (Chauhan & Saini, 2016). NPC is calculated from Eq. (7) and LCOE is calculated from Eq. (9) (HOMER Energy, 2023). Optimum system configurations are displayed after the simulation is completed using a wide variety of tables and graphs to compare and evaluate them according to their economic and technical merits (Anoune et al., 2018).

Electric load in the sample community

One remote northwestern community in Inuvik region, Canada, has been selected for the present case study. The sample community has an average load demand of 2230 kWh/day (813,950 kWh/year), and its peak power consumption is 238.7 kW. Electric load time series data were collected using power meters. The data include apparent power, active power, and voltage. Daily load profiles were extracted from the collected time series data and served as input dataset for simulation. Figure 5 shows the daily profile of the electric load on a typical day at the sample community. The daily cycle of electricity demand begins in the early morning when people wake up and start getting ready for the day. Electricity demand generally peaks between 5 and 8 p.m. As nighttime approaches, electricity consumption slows before repeating the cycle on the following day. Figure 6 shows the seasonal profile of the electric load.

Daily profile of electric load in the sample community

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Seasonal profile of electric load in the sample community

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System configuration and economics

Different configuration scenarios of integrated renewable energy systems have been designed and optimized for the sample community. Table 3 presents the results of the top two optimized configurations. The configuration scenarios are ranked according to their NPC and LCOE. The obtained NPC and LCOE are $3.61 M and $0.255/kWh for scenario 1, and the obtained NPC and LCOE are $3.66 M and $0.262/kWh for scenario 2. These two scenarios have lowest NPCs and LCOEs, as opposed to others assessed, while being capable of satisfying the peak power load demand of the sample community.

Based on the simulation results, the total electricity production by the integrated energy system Scenario 1 is 883,090 kWh/year and the electricity production by the integrated energy system Scenario 2 is 864,193 kWh/year. Thus, the designed energy systems can meet the community’s total electric energy demand. Table 4 presents the breakdown of electricity production and LCOE from the renewable sources for the two scenarios. For Scenario 1, the biomass-based electricity, the electricity produced from solar PV panels and the electricity produced from wind turbines account for 61.2%, 8.08% and 30.7%, respectively. For Scenario 2, the biomass-based electricity, the electricity produced from solar PV panels and the electricity produced from wind turbines account for 68.3%, 5.15% and 26.5%. For both scenarios, the biomass power generator is the primary energy source in the entire energy system. The capital cost and the LCOE of each component in the integrated energy systems are also presented in Table 4.

Figure 7 shows the power output distribution of the solar PV panels with 80 kW rated capacity over a year for Scenario 1. Obviously, electricity is generated during the daytime and little electricity is generated during the winter season. Their mean electricity production is 195 kWh/day, and the total electricity production is 71,321 kWh/year. It is noted that for Scenario 2, the solar PV power output distribution pattern is the same as that of Scenario 1, yet the mean electricity production is 122 kWh/day, and the total electricity production is 44,782 kWh/year. On the other hand, the LCOE from solar PV is the same for both scenarios ($0.087/kWh), which turns out to be independent of the system configurations but is determined by local radiation conditions and solar cell efficiency. Solar PV has the advantages of low operational and maintenance costs. However, it has intermittent characteristics, as shown in Fig. 7.

Power output distribution of the solar PV panels with 80 kW rated capacity at the sample location for 365 days. Hours of operation: 3615 h/year

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Figure 8 illustrates the power output distribution of the wind turbines with 130 kW rated capacity for 365 days for Scenario 1. The mean electricity production of the wind turbines is 724 kWh/day, and their total electricity production is 271,036 kWh/year. As to Scenario 2, the pattern of the power output distribution of wind turbines is similar to what is shown in Fig. 8, but their mean electricity production is reduced to 623 kWh/day, and their total electricity production is reduced to 229,339 kWh/year. For both scenarios, the LCOE is the same (Table 4), the capacity factor of the wind turbines is 23.6%, and the hours of their operation are 7189 h/year in the sample community. In addition, it is observed that the solar power and wind power are consistent with the available solar and wind resources.

Power output distribution of the wind turbines with 130 kW rated capacity days at the sample location for 365. Hours of operation: 7189 h/year

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Here, it is worth noting that renewable integration can be a critical element of a net-zero future, which will reduce reliance on fossil fuels and lower carbon emissions, resulting in far-reaching benefits for society. In other words, integrating renewable energy sources is among the key strategies that can address climate change while accelerating the transition to a green economy. Canada has been committed to clean electricity in more than 200 remote communities that still depend on carbon-intensive diesel power by 2035. The results presented above show that the proposed integrated renewable energy systems can well satisfy the electric energy demand of the studied community, and the LCOE appears to be attractive for electrification in remote communities although carbon credit has not been considered (Lovekin & Heerema, 2019). The results of this study would help support the decision-making regarding the adoption of the clean energy technologies and energy transitions.

Sensitivity analysis

A sensitivity analysis can assess which variables have the greater impact on the economic indicator NPC of a power system. Table 5 shows the results of the sensitivity analysis. The analysis has been conducted by changing the values of the variables independently. It is observed that an increase in component costs, inflation rate and biomass price leads to increases in the NPC but to different extents. For instance, a 20% increase in biomass-based generator capital cost gives rise to 4.98% and 6.75% increases in the NPC for Scenarios 1 and 2, respectively, while a 20% increase in the capital costs of solar PV panel, wind turbine and battery bring about relatively less increases in the NPC.

On the other hand, the increase in discount rate and conversion efficiencies leads to decreasing the NPC. A 20% rise in discount rate results in quite a significant decrease in the NPC, with the NPC variations being − 7.32% and − 6.14% for Scenarios 1 and 2, respectively. The implication is that the discount rate on capital investment has the greater impact on the economic viability of the renewable energy systems. In contrast, the same rise in inflation rate leads to the positive NPC variations of 6.13% and 4.97% for the two configurations. Moreover, Table 5 shows that the increase in the existing efficiency of biomass-based generator, wind turbine or solar PV panel by 10% results in an NPC change of − 1.23% to − 1.51% for Scenario 1, and an NPC change of − 1.02% to − 1.62% for Scenario 2. This suggests that any efficiency improvements in the renewable energy technologies will reduce the NPC of an integrated renewable energy system and thus increase the economic competitiveness of the integrated energy system.

Combining solar PV, wind turbine, biomass-based generator and battery can constitute integrated renewable energy systems for applications in Canada’s remote communities. The integrated energy systems are investigated and shown to be a strong solution to supply clean electricity to the communities through the case study. Integrating multiple renewable energy sources counteracts the weaknesses of one stochastic renewable energy source with the strengths of another. The developed methodology is proven to be effective and useful in the design and optimization of integrated renewable energy systems. Different system configurations consisting of solar PV panels, biomass-based generator, wind turbines and batteries are designed and optimized for electrification in a remote sample community. The obtained results show that for the top two optimized design scenarios, the biomass-based electricity accounts for 61.2% and 68.3% of the total electricity produced by the integrated energy systems, the electricity produced from solar PV panels accounts for 8.08% and 5.15%, and the electricity produced from wind turbines accounts for 30.7% and 26.5%, respectively. The capacity value of the biomass power generator is 270 kW in the two chosen optimized system scenarios, while the capacity values of solar PV panels are 80 kW and 50 kW and wind turbines are 130 kW and 110 kW, respectively. The proposed energy systems effectively satisfy the electric energy demand of the remote northwestern community while their NPC and LCOE are minimized. The sensitivity analysis reveals that increases in discount rate and conversion efficiencies result in a decrease in the NPC, whereas increases in the component costs, inflation rate and biomass price result in an NPC increase. It is found that the variations in biomass to power equipment cost, discount rate and inflation rate result in the largest changes in the NPC. The present study illustrates that the integrated renewable energy systems can be an effective and applicable approach for electrification in remote communities.

Funding for this work was provided by Natural Resources Canada through the Program of Energy Research and Development.

Authors and Affiliations

1. Natural Resources Canada, CanmetENERGY Technology Centre, 1 Haanel Drive, Ottawa, ON, K1A 1M1, Canada

   Kuanrong Qiu & Evgueniy Entchev

Contributions

KQ: conceptualization, methodology, modeling, writing—original draft. EE: validation, writing—review and editing.

Corresponding author

Correspondence to Kuanrong Qiu.

Competing interests

The authors declare that they have no competing interests.

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