Key Economic Drivers Enabling Municipal Renewable Energy Communities’ Benefits in the Italian Context
Abstract
:1. Introduction
1.1. Renewable Energy Communities as Defined by the Renewable Energy Directive 2001/2018
1.2. Renewable Energy Communities as Transposed in the Italian Legislation
2. Methodology
2.1. RECs Performance: Variables and Indicators
- Solar radiation availability: this parameter depends on the location and determines the overall energy production potential.
- Installed photovoltaic size (in peak kilowatts): the installed peak power determines the electrical production and must be chosen according to the number and type of a REC’s members.
- Capital expenditure (CAPEX) represents the initial investment costs of the RES power system.
- Operational expenditure (OPEX), including the RES power plant maintenance costs and insurance, as well as the REC management annual costs.
- Electricity purchase price: since the operational lifetime of the system is normally above 25 years, it is very difficult to estimate this variable for such a long time span, given the wide fluctuations witnessed in recent periods influenced by external factors and events.
- The public incentives granted to the REC, i.e., subsidised loan and/or a premium tariff on shared energy in the REC that applies in the Italian legislation.
- The interest rate, in case of a loan.
- Net Present Value (NPV): The NPV measures the investment’s profitability by calculating the sum of annual cash outflows (Ct) generated by the REC over its 20-year operational span (N = 20), discounted to the present day (depending by the discount rate i). From the perspective of one REC, any bank loan (if available) is deducted from the initial investment (C0), and the loan repayment is included as a cost in the subsequent cash flows until it has been fully repaid.
- Internal Rate of Return (IRR): The IRR is determined by finding the interest rate at which the NPV becomes zero, indicating the rate of return achieved by the investment, and can be compared to the market interest rate to verify the profitability.
- Payback Period: The payback period, often referred to as the payback time, denotes the number of years required for the investment to recoup its initial cost and commence generating positive returns. It is calculated by solving Equation (1) with respect to time for a predefined value of i.
- Photovoltaic (PV) System Production: this is influenced by geographical position, tilt, orientation and obstacles.
- Physical Self-Consumed Energy: i.e., the energy directly utilised by the devices connected to the Renewable Energy System (RES) before the electric meter that connects it with the grid (e.g., in a residential system all the energy utilised by the appliances and lighting system in the household).
- Energy fed into the grid: this is the surplus energy obtained by subtracting the physical self-consumed energy from the PV plant production, which is then injected into the electrical grid.
- Shared energy: as defined by ARERA (the Italian energy authority), shared energy represents the minimum energy, on an hourly basis, resulting from the net difference between the electrical energy fed into the system and the electrical energy drawn from the connection points relevant to a group of renewable energy self-consumers or a renewable energy community (i.e., it is the energy that is put into the grid by a prosumer and is simultaneously utilised by the other members of the REC).
- Surplus production: i.e., the energy fed into the grid, minus the shared energy, resulting in the net surplus energy put into the grid.
2.2. Base Case Scenario Description
2.3. REC Variants
2.4. The Simulation Tool
- General Data: the user is prompted to assign a name to the project and select the location (province and municipality). Additionally, the configuration must be specified as either renewable energy community or collective self-consumption (i.e., all members and the PV plant are in the same building). Furthermore, the grid connection for the PV plant needs to be selected.
- Consumption Units: this section includes the input data related to electricity consumption and corresponding members: prosumer (the school in our case) and the consumers, which are organised into clusters (the households). Each cluster is characterised by specific information related to the building (thermal envelope quality), equipment (heating, cooling, domestic hot water), electrical consumption (data availability and values), and the occupants’ profile.
- Production Plant: this section collects the technical information on the PV plant.
- Economic and Financial Parameters: this section includes the economic parameters, such as average purchase and sale prices of electricity, initial operating costs, annual operating costs (including the plant maintenance and REC operational costs), and financial parameters such as the discount rate, inflation rate, and information related to the bank loan.
3. Results
3.1. Base Case
3.2. Sensitivity Analysis
3.2.1. Location
3.2.2. PV Size
3.2.3. Investment Costs
3.2.4. Energy Prices
4. Discussion
4.1. Best-Case and Worst-Case Scenarios
- In the worst-case scenario, we assume that all variables are set in order to decrease the benefits (or increase the costs) for the REC members as much as possible. The REC is located in Milan (with the lowest PV production among those evaluated), with an installed capacity of 100 kWp and 50 consumers connected (worst combination). The turnkey unit cost of the PV plant is set at the highest value within the range (1600 EUR/kWp), and the average purchase price of electricity corresponds to the lowest value (0.25 EUR/kWh). Moreover, the operational costs are increased to 7500 EUR/year (respect the 4400 EUR of the best case), while the loan is maintained to two-thirds of the CAPEX with an interest rate of 3% (as for the base case).
- In the best-case scenario, we assume that all variables are set to increase the benefits (or decrease the costs) for the REC members as much as possible. The REC is in Palermo (with the highest PV production), with an installed capacity of 100 kWp and 100 consumers connected. The unitary turnkey cost of the PV plant is set at the lowest value within the range (1200 EUR/kWp), and the average purchase price of electricity is the maximum value (0.40 EUR/kWh). Additionally, a loan with a 0% interest rate is evaluated (i.e., from a public loan) to once again cover two-thirds of the CAPEX.
4.2. Benefits: For Whom?
5. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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ID | Location | PV Size [kWp] | PV Initial Cost [EUR/kWp] | Electricity Purchase Price [EUR/kWh] |
---|---|---|---|---|
BASE | Rome | 100 | 1400 | 0.30 |
1a | Milan | 100 | 1400 | 0.30 |
1b | Palermo | 100 | 1400 | 0.30 |
2a | Rome | 50 | 1400 | 0.30 |
2b | Rome | 200 | 1400 | 0.30 |
3a | Rome | 100 | 1200 | 0.30 |
3b | Rome | 100 | 1600 | 0.30 |
4a | Rome | 100 | 1400 | 0.25 |
4b | Rome | 100 | 1400 | 0.40 |
Installed power | 50–100–200 kWp |
Cells technology | Crystalline silicon |
Type of installation | Rooftop integrated |
Tilt | 35° |
Orientation | 0° |
System loss | 14.0% |
Total loss | 22.0–22.9% |
Extraordinary maintenance periodicity | 12 years |
Average annual yield loss | 1% |
CAPEX and OPEX | |
---|---|
Initial unit PV cost | 1200–1400–1600 EUR/kWp |
Annual O and M costs | 4400 EUR/year |
Average Electricity Prices | |
Purchase price | 0.25–0.30–0.40 EUR/kWh |
Sell price | 0.12–0.15–0.22 EUR/kWh |
Financial Parameters | |
Discount rate | 4% |
Inflation | 2% |
Loan | 2/3 of the initial investment |
Annual loan interest rate | 3% |
Loan duration | 10 years |
Number of annual loan instalments | 1 |
Annual Electricity Consumption and Production (at Year 1) | |
---|---|
Total electricity consumption | 343,540 kWh |
Daytime electricity consumption | 175,372 kWh |
PV plant production | 137,624 kWh |
Energy self-consumed | 19,175 kWh |
Shared Energy | 81,892 kWh |
Energy fed into the grid | 118,449 kWh |
Surplus production | 36,557 kWh |
Energy and Environmental Indicators | |
Physical self-consumption index | 13.93% |
Virtual self-consumption index (shared energy) | 59.50% |
Total self-consumption index | 73.44% |
Self-sufficiency index | 29.42% |
Annual avoided CO2 emissions | 45.40 t CO2 |
Analysis of the Investment Costs (at Year 1) | |
Total area of the PV modules | 670 m2 |
Initial plant cost | 140,000 EUR |
Equity | 46,700 EUR |
Loan | 93,300 EUR |
Fiscal deductions | 0 EUR |
Annual Savings, Revenues and OPEX (at Year 1) | |
Savings from physical self-consumption | 5753 EUR/year |
Revenues from electricity fed into the grid | 17,767 EUR/year |
Total savings and revenues | 23,520 EUR/year |
OPEX | 4400 EUR/year |
Annual loan payment (for first 10 years) | 16,076 EUR/year |
Incentives and Reimbursement of Tariff Components (at Year 1) | |
Incentive on shared energy | 9008 EUR/year |
Reimbursement of network charges | 673 EUR/year |
Financial Indicators | |
Net present value (after 20 years) | EUR 274,617 |
Internal rate of return (IRR) | 39.4% |
Payback time | 2.7 years |
Output | Worst Case | Best Case |
---|---|---|
Physical self-consumption | 15.8% | 13.8% |
Virtual self-consumption | 43.0% | 59.5% |
Total self-consumption | 58.7% | 73.3% |
Energy self-sufficiency | 37.1% | 29.6% |
Net present value (after 20 years) | EUR 51,713 | EUR 478,021 |
Internal rate of return (IRR) | 9.5% | 88% |
Payback time | 13.6 years | 1.1 years |
Distribution Approach | Worst Case | Base Case | Best Case | |
---|---|---|---|---|
Equal | 68 EUR/year | 121 EUR/year | 244 EUR/year | |
Differentiated | 50% to 20% | 171 EUR/year | 303 EUR/year | 609 EUR/year |
50% to 80% | 43 EUR/year | 76 EUR/year | 152 EUR/year |
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Ruggieri, G.; Gambassi, R.; Zangheri, P.; Caldera, M.; Verde, S.F. Key Economic Drivers Enabling Municipal Renewable Energy Communities’ Benefits in the Italian Context. Buildings 2023, 13, 2940. https://doi.org/10.3390/buildings13122940
Ruggieri G, Gambassi R, Zangheri P, Caldera M, Verde SF. Key Economic Drivers Enabling Municipal Renewable Energy Communities’ Benefits in the Italian Context. Buildings. 2023; 13(12):2940. https://doi.org/10.3390/buildings13122940
Chicago/Turabian StyleRuggieri, Gianluca, Rebecca Gambassi, Paolo Zangheri, Matteo Caldera, and Stefano F. Verde. 2023. "Key Economic Drivers Enabling Municipal Renewable Energy Communities’ Benefits in the Italian Context" Buildings 13, no. 12: 2940. https://doi.org/10.3390/buildings13122940
APA StyleRuggieri, G., Gambassi, R., Zangheri, P., Caldera, M., & Verde, S. F. (2023). Key Economic Drivers Enabling Municipal Renewable Energy Communities’ Benefits in the Italian Context. Buildings, 13(12), 2940. https://doi.org/10.3390/buildings13122940