Submitted:
20 June 2026
Posted:
24 June 2026
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Abstract
Keywords:
1. Introduction
1.1. Problem Statement
1.2. Related Work
1.3. Objectives and Scope
- to develop an accurate steady-state model of the site network in OpenDSS and MATLAB based on the approved technical drawings;
- to analyse the voltage profile of building blocks A, B and C under PV penetration levels of 0%, 50% and 100%;
- to evaluate the loading of the distribution transformers (800 kVA and 315 kVA) and quantify the daytime peak-shaving benefit; and
- to determine the hosting capacity of the network relative to the statutory voltage limits defined by the EN 50160 standard.
2. Materials and Methods
2.1. Study Area and Test System
2.2. Simulation Platform
2.3. Network Configuration and Component Modelling
2.4. PV Penetration Scenarios
2.5. Load-Flow Analysis and Voltage Criteria
2.6. Voltage-Deviation Calculation
2.7. 24-Hour Profiles and Transformer-Loading Analysis
2.8. Assumptions and Limitations
3. Results
3.1. Source-Bus Operating Conditions
3.2. Bus-Voltage Profiles across PV Penetration Scenarios
3.3. Voltage-Deviation Analysis
3.4. 24-Hour Temporal Analysis
3.5. Transformer-Loading Analysis
3.6. Cross-Validation: MATLAB versus OpenDSS
4. Discussion
5. Conclusions
- All bus voltages remained within the 0.95–1.05 pu range across all scenarios, confirming that the network can safely accommodate up to 100% rooftop PV penetration.
- The maximum voltage rise caused by PV integration was only +0.67% (MATLAB) / +0.360% (OpenDSS) at the B1+B2 block, far below the ±5% limit.
- Grid power consumption fell from 726.4 kW (S1) to 191.7 kW (S3), a reduction of 73.6%, demonstrating significant self-supply potential; system losses decreased in absolute terms (0.00850 → 0.00480 MW) but rose in percentage terms (1.171% → 2.505%) owing to reverse power flow.
- Transformer loading decreased markedly with PV integration, with TR-A123 peak loading dropping from about 53% to about 16% in S3, extending equipment life.
- Bus OT was identified as the critical bus, with an initial violation of 0.928 pu; corrective measures (a cable upgrade to NYY 4×16 mm2 and a +1.5% tap on TR-A123) raised it to 0.975 pu, achieving full compliance.
- proceed with full rooftop PV installation, as all voltage standards are met and transformer capacities are not exceeded;
- retain the upgraded NYY 4×16 mm2 cable on the OT feeder in the final construction design;
- install revenue-grade bidirectional meters at the PV-connected buses to monitor reverse power flows;
- consider reactive-power (Q) control for the PV inverters to stabilise voltages as future load growth reduces safety margins; and
- review protection-relay settings, since the very low transformer loading in S3 (~16%) may affect minimum fault-detection sensitivity.
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
Appendix A. Electrical Project Drawings






Appendix B. Technical Component Specifications and Simulation Data
Appendix B.1. Transformer Parameters
| Transformer | Rated | U | Load loss | No-load loss | Tap |
|---|---|---|---|---|---|
| TR-A123 | 800 kVA | 4.0% | 0.5% | 0.1% | 1.015 |
| TR-B12 | 315 kVA | 4.0% | 0.5% | 0.1% | 1.000 |
| TR-C12 | 315 kVA | 4.0% | 0.5% | 0.1% | 1.000 |
Appendix B.2. Conductor Impedance Characteristics
| Feeder | Cable | R1 (Ω/km) | X1 (Ω/km) | Ampacity |
|---|---|---|---|---|
| A1+A2+A3 | 2×(3×185/95 mm2) NYY | 0.082 | 0.0335 | ~728 A |
| B1+B2 & C1+C2 | 3×150/70 mm2 NYY | 0.206 | 0.068 | ~319 A |
| Common (OT) | 4×16 mm2 NYY | 1.15 | 0.082 | ~87 A |
Appendix B.3. Selected 24-Hour Load and PV Multipliers
| Period | Residential load (pu) | PV generation (pu) |
|---|---|---|
| 00:00–04:00 (night) | 0.20–0.30 | 0.00 |
| 08:00 (morning ramp) | 0.60 | 0.50 |
| 10:00–12:00 (solar peak) | 0.60–0.65 | 0.90–1.00 |
| 16:00 (afternoon decline) | 0.75 | 0.25 |
| 18:00 (evening peak) | 1.00 | 0.00 |
| 22:00 (late evening) | 0.60 | 0.00 |
Appendix B.4. Regulatory and Inverter Specifications
References
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| Building block | Apparent-power rating | Active-power demand |
|---|---|---|
| A1+A2+A3 | 800 kVA | 347.36 kW |
| B1+B2 | 315 kVA | 151.56 kW |
| C1+C2 | 315 kVA | 147.57 kW |
| Common (OT) | — | 71.42 kW |
| Branch | Demand (kW / kvar) | Transformer | Cable (15 m) |
|---|---|---|---|
| A1+A2+A3 | 347.36 / 167.92 | 800 kVA, tap 1.015 | 2×(3×185/95 mm2) NYY |
| B1+B2 | 151.56 / 73.27 | 315 kVA, tap 1.000 | 3×150/70 mm2 NYY |
| C1+C2 | 147.57 / 71.34 | 315 kVA, tap 1.000 | 3×150/70 mm2 NYY |
| Common (OT) | 71.42 / 44.26 | — | 4×16 mm2 NYY (36 m) |
| Scenario | Description | PV penetration | Installed PV (A/B/C, kWp) |
|---|---|---|---|
| Base Case / S1 | Network without rooftop PV | 0% | 0 / 0 / 0 |
| Low Penetration | Limited rooftop PV integration | 25% | 40 / 28 / 21 |
| Moderate / S2 | Medium rooftop PV integration | 50% | 80 / 55 / 42 |
| High / S3 | Full rooftop PV integration | 100% | 160 / 110 / 84 |
| Parameter | Phase A | Phase B | Phase C |
|---|---|---|---|
| Voltage magnitude (pu) | 0.998004 | 0.998004 | 0.998004 |
| Voltage angle (°) | −0.03 | −120.03 | +119.97 |
| Current magnitude (A) | 6.87916 | 6.87916 | 6.87916 |
| Active power (kW/phase) | 63.8991 | 63.8991 | 63.8991 |
| Reactive power (kvar/phase) | −120.902 | −120.902 | −120.902 |
| Total 3-phase active | 191.697 kW | — | — |
| Total 3-phase reactive | −362.706 kvar | — | — |
| Scenario | A1+A2+A3 | B1+B2 | C1+C2 | Common (OT) |
|---|---|---|---|---|
| Base Case (S1, 0% PV) | 1.0029 | 0.9895 | 0.9869 | 0.9999 |
| Moderate (S2, 50% PV) | 1.0039 | 0.9913 | 0.9882 | 0.9999 |
| High (S3, 100% PV) | 1.0049 | 0.9931 | 0.9896 | 0.9999 |
| Building block | Low (25%) | Moderate (50%) | High (100%) | Limit |
|---|---|---|---|---|
| A1+A2+A3 | +0.09% / +0.099% | +0.17% / +0.178% | +0.35% / +0.201% | ±5.00% |
| B1+B2 | +0.16% / +0.178% | +0.32% / +0.360% | +0.67% / +0.360% | ±5.00% |
| C1+C2 | +0.10% / +0.133% | +0.21% / +0.270% | +0.44% / +0.270% | ±5.00% |
| Common | +0.00% | +0.00% | +0.00% | ±5.00% |
| Transformer | Rated (kVA) | Base-case peak | S3 midday load | Reduction | Status |
|---|---|---|---|---|---|
| TR-A123 | 800 | ~48% | ~31% | ~17% | Normal |
| TR-B12 | 315 | ~52% | ~3% | ~49% | Normal |
| Parameter | MATLAB | OpenDSS | Difference | Agreement |
|---|---|---|---|---|
| Source voltage (pu) | 1.000 (set) | 0.998004 | 0.002 pu | Good |
| A-block base voltage | ~0.990 | ~0.990 | <0.001 pu | Excellent |
| Max voltage rise (S3) | +0.67% (B1+B2) | +0.360% (B1+B2) | 0.31% | Good |
| S3 A-block voltage | 0.994 | 1.0049 | 0.011 pu | Good |
| ±5% compliance | Yes | Yes | — | Consistent |
| Overvoltage violations | None | None | — | Consistent |
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