Developing Novel Technologies and Services for Intelligent Low Voltage Electricity Grids: Cost–Benefit Analysis and Policy Implications
Abstract
:1. Introduction
1.1. Objective and Research Questions
- RQ1. How can the DSO manage intelligently the LV grid and improve the grid performance in terms of efficiency and hosting capacity?
- RQ2. What concrete and quantifiable benefits (based on defined KPIs) can be achieved from the proposed RESOLVD solution?
- RQ3. Are the RESOLVD hardware and software solutions economically viable and can their adoption be economically justified when compared to the business-as-usual (BAU) scenario, i.e., without RESOLVD? What will be the impact of scaling up towards large-scale deployment of RESOLVD solutions and what is its sensitivity with respect to reduction in major costs, such as software and battery?
- RQ4. What implications does RESOLVD have to the energy policy, technology, and businesses?
1.2. Paper Organization
2. Review on Intelligent Distribution Grids
2.1. Observability of the Grid
2.2. Integration of Energy Storage Systems
2.3. Decision Support Systems for the DSOs
2.4. Integration of IT Systems at the DSO Level
2.5. Cost–Benefit Analysis for Relevant Low TRL Solutions
3. RESOLVD Concept and Demonstration Pilot
3.1. The Project Concepts
- Improvement of low-voltage grid observability.
- Critical event forecasting. This includes day-ahead forecasting of congestions and over/under voltages due to daily variations in demand profiles with the presence of PV generation.
- Early fault detection by exploiting the grid observability and redundancy of measurements.
- Island management; this includes the detection of uncontrolled islanding situations and the management of ESS and frequency control in controlled LV islands.
- Power quality improvement and loss reduction; this includes compensation of harmonics reactive power, and phase balancing with power electronics (PED).
- Reduction of technical losses in the network by reducing imported energy and maximizing the use of renewable energy locally produced.
- Cyber security; the design of subsystems and further integration has been submitted to rigorous analysis and tests to assure the cybersecurity of the whole solution.
- -
- Switchgears: to reconfigure the grid to avoid critical events (congestions and/or over/sub voltages)
- -
- Batteries: schedule the charge/discharge of batteries according to efficient operation goals (reduce energy exchange at the substation level, peak reduction, maximal use of RES locally generated)
- -
- Power electronics: its activation allows reduction of losses and improves quality by compensating harmonics and reactive, balancing phases, and compensating voltage variation by injecting reactive power.
3.2. The Demonstration Pilot
4. Cost–Benefit (CBA) Methodology
4.1. CBA Process Steps for Smart Grid Projects
4.2. Economic Indicators for CBA
- Costs: all major costs for the hardware and software development, installation, personnel, services cost, such as cyber security.
- Shadow price: for calculating willingness to pay for SaaS, a shadow price is considered based upon other existing software used by the DSO.
- Benefits from technical indicators: in the project, a total of 12 indicators, nine technical KPIs, including the three control indicators (CI), have been defined, which are converted into monetary values. The process of converting these indicators to monetary value is qualitatively described in Table 2. Details on the project indicators can be found under public deliverable D5.1 of the RESOLVD project [42].
- Benefits from remuneration: these are considered based on the DSOs savings from the remuneration formula and described in the next sub-section.
5. Results and Discussion
5.1. Developed Technology, Novelty, and Main Findings (Linked to RQ1)
5.2. Quantified RESOLVD Benefits (Linked to RQ2)
5.3. Cost–Benefit Analysis (Linked to RQ3)
5.3.1. Economic Viability of RESOLVD Technology
5.3.2. Scenario Test Based on the DSO Willingness to Pay (WTP) of the Software Service
5.4. Replication and Market Potential of RESOLVD Solution
6. RESOLVD Implications on Business and Policy (Linked to RQ4)
6.1. Business Implication
6.2. Policy and Regulatory Implications
7. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Abbreviations
AMI | Advanced Metering Infrastructure |
BAU | Business As Usual |
BMS | Battery Management System |
CAPEX | Capital Expenditures |
CBA | Cost–Benefit Analysis |
CIM | Common Information Model |
DER | Distributed Energy Resource |
DG | Distribution Generation |
DMS | Distribution Management System |
DSO | Distribution System Operator |
EES | Electrical Energy Storage |
EF | Energy Forecaster |
GIS | Geographic Information System |
GW | Gateway |
IED | Intelligent Electronic Device |
ILEM | Intelligent Local Energy Manager |
JRC | Joint Research Centre |
KPI | Key Performance Indicator |
LV | Low Voltage |
MDMS | Metering Data Management System |
MV | Medium Voltage |
OPEX | Operating Expenditure |
PCS | Power Conversion System |
PED | Power Electronic Device |
PMU | Phasor Measurement Unit |
PQM | Power Quality Monitoring |
RQ | Research Question |
RES | Renewable Energy Source |
SaaS | Software-as-a-Service |
SCADA | Supervisory Control and Data Acquisition |
SG | Smart Grids |
SGT | Smart Grid Technologies |
SGAM | Smart Grid Architecture Model |
SM | Smart Meter |
SS | Secondary Substation |
TOTEX | Total Expenditure |
TSO | Transmission System Operator |
WAMS | Wide Area Monitoring System |
WTP | Willingness-To-Pay |
Appendix A
Investment Costs (Development and Service) | Costs in EUR |
Intelligent Local Energy Manager (ILEM) development (PED + Personnel+ batteries) | xxxxxxx |
Remote Terminal Unit (RTU) | xxxx |
Low voltage switchgear (LVSG) | xxxx |
Phasor Measurement Unit (PMU) | xxxx |
Phasor quality meter (PQM) | xxxx |
Operation cost(effort) | xxxx (DSO retribution) |
PSS power system supply | xxxx |
Gateway | xxxx |
Router | xxxx |
EBS software platform (development cost) | xxxxxxx |
LVD-DST software platform/forecasting and scheduling | xxxxxxx |
Cyber security service | xxxxxx |
Other investment costs | |
Replacement cost | xxxx |
Residual cost | (xx) |
Revenue/Savings | Savings in EUR per Year |
KPI-1: Power loss reduction due to waveform quality improvement | xxx |
KPI-2 Improvement of the energy profile in the secondary substations | xxxx |
CI-1 Efficiency rate of the PED and the energy storage system | -xxx |
KPI-3 Increase of DERs hosting capacity in LV network | xxxxx |
KPI-4 Reduction of DSO investment | xxxxx |
CI-2 DSO operation expenditures with respect to the BAU solutions | xxxx |
KPI-5 Percentage of improvement in line voltage profiles with power injection and consumption | xx |
KPI-6 Rate of prevented critical events in the LV grid due to forecasting and remote control of grid actuators | x |
KPI-7Quality of online event detection in LV grid | x |
KPI-8 Quality and time needed for awareness and localization of grid fault MV grid (per incident 1785) | xxxx |
KPI-9 Quality of LV grid operation in island mode | xxxx |
CI-3 Waveform quality in LV grid | xx |
Appendix B
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Secondary Substation (SS) | SS (A) 528 | SS (B) 0030 |
---|---|---|
Transformer rated power | 250 kVA | 630 kVA |
Total contracted power | 138.6 kW | 127.8 kW |
Contracted power of line in the pilot | 58.3 kW | 56.9 kW |
PV power installed in the pilot | 12.5 kW | 9.9 kW |
Project Indicators | Basic Assumptions Considered to Calculate the Benefit | Linked Remuneration Variables |
---|---|---|
KPI1: Power loss reduction due to waveform quality improvement | The annual average electricity increases in the pilot feeders (17 kW) multiplied by the % loss and compared with the change from the business-as-usual scenario (BAU). | |
KPI2: Improvement of the energy profile in the secondary substations | In SS where PEDs are managing renewable sources. The PV energy does not flow from all distribution infrastructures from TSO link. | data 1 |
CI1: Efficiency rate of the PED and the energy storage system | Consumption of Vdc bus, batteries technologies and PED auxiliary internal consumptions. | , |
KPI3: Increase in DER hosting capacity in LV network | PED, batteries, and auxiliary system internal consumptions. | |
KPI4: Reduction in DSO investment | In terms of traditional infrastructure investment and assuming an average distance of 100 m multiplied by new LV feeder cable plus the cost of assets upgrade. | |
CI2: DSO operation expenditures with respect to the BAU solutions | Regarding the remuneration for the operation and maintenance, the rule in force until 2020 (RD 1048/2013 + Order IET/2660/2015) differentiates between O&M of electrical assets (which is remunerated by unit value) and O&M of nonelectrical assets (which is remunerated by invoice). The O&M amount of electrical assets ranges from 3% to 5% of the unit investment reference value. | |
KPI5: Percentage of improvement in line voltage profiles with power injection and consumption | The real and reactive power not supplied from the primary substation and provided from PED in the maximum consumption time and assuming that the active power was charged in the storage system when there was a surplus in the valley period. | - |
KPI6: Rate of prevented critical events in the LV grid due to forecasting and remote control of grid actuators | Assuming average time response as a traditional way, the customer from the fault to fuse restoration is two hours. Moreover, the usual time that a user calls DSO to communicate the fault is 10 min on average. Average energy in the pilot feeders multiplied by the events that feeder fuses are blown per year assumed by DSO. | - |
KPI7: Quality of online event detection in LV grid | Fast detection of short circuits and severe faults that lead to protection (fuses). The time difference between rapid detection (the time of occurrence) compared to a conventional method in which fuse actions are protections where they are reported. I have considered it to involve a reduction in response time x kWh considering the number of end-users affected due to fuse blow. | |
KPI8: Quality and time needed for awareness and localization of grid fault MV grid | To localize an MV fault and isolate part of the grid on average from the historic SCADA registers in 5 h, consider wage of operator per hour. As result of this KPI, it is possible locate the fault and save in average 3.5 h. Moreover, it avoids the assets stress. | |
KPI9: Quality of LV grid operation in island mode | It was just tested during the functional test. The functional testcreated an electrical island for 85 min. | , & |
CI3: Waveform quality in LV grid | Only affect in the part of the upstream grid from PED until the primary substation is connected the pilot feeder. |
Category | Indicator | Business as Usual (BAU) without RESOLVD | After (with) RESOLVD | Saving in EUR/Year |
---|---|---|---|---|
Efficiency | KPI-01: Power loss reduction due to waveform quality improvement (W/Ω) | Unknown | 166.7 W/Ω | <1000 |
KPI-02: Improvement of the energy profile in the secondary substations Sub-indicators: (i) Losses T&D (%) (ii) Locally generated energy use (%) (iii) Maximum peak (%) | (i) Losses T&D is 7.3% at each SS, which is at SS-00528: 9.49 kW, SS-0030: = 8.3 kW.; (ii) Locally generated energy use is: 2.8% and 1.27%; | (i) SS-00528: Not affected because PED is not interacted as a normal exploitation. SS-0030 reduced T&D losses = 0.5% (ii) and (iii) Locally generated energy use and maximum peak (%) has no registered changes | 1000–5000 | |
Planning | CI-01: Efficiency rate of the PED and the energy storage system Note: The benefit of this indicator to DSO is in higher self-consumption rate (kW). | Without PED (no PED implemented) | Change registered: −4,2 kW | <1000 |
KPI-03: Increase in DER hosting capacity in LV network (%kVA with respect to the current maximum limit) | 138 kVA | 189 kVA Change registered: 36.95% | >25,000 | |
KPI-04: Reduction in DSO investment (%) | Retribution | Retribution change registered: 22% | >25,000 | |
CI-02: DSO operation expenditures with respect to the BAU solutions (EUR per year) | The O&M amount of electrical assets ranges from 3% to 5% of the unit investment reference value. | Considering an investment of EUR 57.000 as a usual new building of network assets at LV level. | 1000–5000 | |
Quality of service | KPI-05: Percentage of improvement in line voltage profiles with power injection and consumption (%) | NA | 0.03 | <1000 |
KPI-06: Rate of prevented critical events in the LV grid due to forecasting and remote control of grid actuators Sub indicators: (i) Precision of forecasting (%) (ii) Time to respond to critical event (minutes) | (i) No previous data available; (ii) It was taking 120 min | −15–40% (*) (**) −2 min Change registered: 118 min N.B. (*) (**) are kept anonymous. | <1000 | |
KPI-07: Quality of online event detection in LV grid Sub-indicators: (i) Accuracy (%) (ii) Precision (%) (iii) Miss Detections (%) (iv) False Alarms (%) (v) Detecting time (s) (vi) Informing delay (s) | (i) No previous data (ii) No previous data (iii) No previous data (iv) No previous data (v) No previous data (vi) 120 min | (i) 97.5% (ii) 93.5% (iii) 0% (iv) 3.8% (v) 1 s (vi) 35–400 s | <1000 | |
KPI-08: Quality and time needed for awareness and localization of grid fault MV grid (seconds) | NA because RESOLVD is focused on LV level. This KPI, is focused in MV level. Moreover, the KPI measures quality of effectivity of PMU | 2.04 s Impact MV (indirect benefit to the DSO due to PMU) | 1000–5000 (indirect saving from MV) | |
KPI-09: Quality of LV grid operation in island mode (hours) | 0.33 h (avg. from previous year) | 1.417 h Changed registers: 1.087 h | 1000–5000 | |
CI-03: Waveform quality in LV grid (%) | NA (no data before RESOLVD project) | 0.12% | <1000 |
Indicators | 2SS-4 Feeders (Current Pilot) | 8SS-16 Feeders | 10SS-20 Feeders | 12SS-24 Feeders | 24SS-48 Feeders |
---|---|---|---|---|---|
NPV | −459 k | −57 k | 97 k | 226 k | 1054 k |
IRR | −11% | 2% | 6% | 9% | 23% |
Payback period | >10 years | 9th year | 8th year | 5th year | 4th year |
Benefit–cost ratio | 0.5 < 1 | 1.1 > 1 | 1.3 > 1 | 1.4 > 1 | 2.4 > 1 |
Recommendation | Not worth investing in the current pilot size. | Risky to continue with the investment. | Relatively lower IRR; however, it is worth continuing with the investment. | It is worth continuing with the investment. | It is worth continuing with the investment. |
Number of Supply point | <10,000 | 10,000–50,000 | 50,000–100,000 | 100,000–500,000 | 500,000–1,000,000 | >1,000,000 |
Cost per supply point | EUR 1 | EUR 0.2 | EUR 0.1 | EUR 0.02 | EUR 0.01 | EUR 0.001 |
Indicators | ILEM | IT Integration Software | LVD-DST (Decision Support Toolkit) | |||
---|---|---|---|---|---|---|
2SS-4 Feeders | 8SS-16 Feeders | 2SS-4 Feeders | 8SS-16 Feeders | 2SS-4 Feeders | 8SS-16 Feeders | |
NPV | −156 k | 305 k | −323 k | 78 k | −343 k | 58 k |
IRR | −5% | 17% | −11% | 6% | −8% | 6% |
Payback period | >10 years | 4th year | >10 years | 6th year | >10 years | 7th year |
Benefit–cost ratio | 0.8 < 1 | 1.8 > 1 | 0.6 < 1 | 1.3 > 1 | 0.6 < 1 | 1.3 > 1 |
Recommendation | Not worth investing with the current pilot size. | It is worth continuing with the investment. | Not worth investing with the current pilot size. | Longer payback period but worth continuing with the investment. | Not worth investing with the current pilot size. | Longer payback period but worth continuing with the investment. |
Partners | Population (MN) | DSO (<100 K Customers) | DSO (>100 K Customers) | TWh |
---|---|---|---|---|
Spain | 47 | 349 | 5 | 278 |
Norway | 5.4 | 150 | 7 | 118 |
Austria | 8.8 | 138 | 13 | 61 |
Greece | 11.1 | 2 | 1 | 45 |
Slovenia | 2 | 1 | 1 | 13 |
Total | 74.3 | 640 | 27 | 515 |
EU and EEA | 520MN (inc. UK) | 2400 | 190 | 2700 |
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Belay, A.M.; Puranik, S.; Gallart-Fernández, R.; Tuiskula, H.; Melendez, J.; Lamprinos, I.; Díaz-González, F.; Smolnikar, M. Developing Novel Technologies and Services for Intelligent Low Voltage Electricity Grids: Cost–Benefit Analysis and Policy Implications. Energies 2022, 15, 94. https://doi.org/10.3390/en15010094
Belay AM, Puranik S, Gallart-Fernández R, Tuiskula H, Melendez J, Lamprinos I, Díaz-González F, Smolnikar M. Developing Novel Technologies and Services for Intelligent Low Voltage Electricity Grids: Cost–Benefit Analysis and Policy Implications. Energies. 2022; 15(1):94. https://doi.org/10.3390/en15010094
Chicago/Turabian StyleBelay, Alemu Moges, Sanket Puranik, Ramon Gallart-Fernández, Heidi Tuiskula, Joaquim Melendez, Ilias Lamprinos, Francisco Díaz-González, and Miha Smolnikar. 2022. "Developing Novel Technologies and Services for Intelligent Low Voltage Electricity Grids: Cost–Benefit Analysis and Policy Implications" Energies 15, no. 1: 94. https://doi.org/10.3390/en15010094
APA StyleBelay, A. M., Puranik, S., Gallart-Fernández, R., Tuiskula, H., Melendez, J., Lamprinos, I., Díaz-González, F., & Smolnikar, M. (2022). Developing Novel Technologies and Services for Intelligent Low Voltage Electricity Grids: Cost–Benefit Analysis and Policy Implications. Energies, 15(1), 94. https://doi.org/10.3390/en15010094