Evaluation and Analysis of Load Characteristics of Distribution Transformers

Field: Transformer Analysis

China

In-depth Analysis and Key Considerations for Load Characteristic Evaluation

Load characteristic evaluation is a cornerstone of distribution transformer design, directly influencing capacity selection, loss distribution, temperature rise control, and operational economy. The evaluation must be conducted across three dimensions: load type, temporal dynamics, and environmental coupling, with a refined model established based on actual operating conditions.

1. Refined Analysis of Load Types

Classification and Characteristics

Residential Loads: Dominated by lighting and household appliances, with a daily load curve exhibiting dual peaks (morning and evening) and a low annual load factor (approximately 30%–40%).
Industrial Loads: Categorized into continuous (e.g., steel mills), intermittent (e.g., machining), and impact loads (e.g., electric arc furnaces), requiring attention to harmonics, voltage fluctuations, and inrush currents.
Commercial Loads: Such as shopping malls and data centers, characterized by seasonal variations (e.g., summer air conditioning) and nonlinear characteristics (e.g., UPS, frequency converters).

Load Modeling

Employ equivalent circuit models or measured data fitting to quantify power factor (PF), harmonic content (e.g., THDi), and load rate fluctuations.

2. Dynamic Analysis Across Temporal Dimensions

Daily Load Curve

Derived from field monitoring or standard curves (e.g., IEEE), highlighting peak and off-peak periods and their durations.
Example: An industrial park’s daily curve reveals dual peaks from 10:00–12:00 and 18:00–20:00, with nighttime load rates below 20%.

Annual Load Curve

Accounts for seasonal variations (e.g., summer cooling, winter heating) and predicts future load growth using historical data.
Key Metrics: Annual maximum load utilization hours (Tmax), load factor (LF), and load coefficient (LF%).

3. Environmental Coupling and Correlation Assessment

Temperature Impact

Every 10°C increase in ambient temperature reduces transformer rated capacity by approximately 5% (based on thermal aging models), necessitating overloading capability verification.

Altitude Impact

Every 300m increase in altitude decreases insulation strength by ~1%, requiring insulation design adjustments or capacity derating.

Pollution Severity

Categorized per IEC 60815 (e.g., light, heavy pollution), influencing bushing and insulator selection and creepage distance.

4. Evaluation Methods and Tools

Measurement-Based Approach

Collects real-world load data via smart meters and oscillographs, followed by statistical analysis (e.g., load rate distribution, harmonic spectrum).

Simulation-Based Approach

Utilizes software like ETAP or DIgSILENT to model power systems under various scenarios.

Empirical Formulas

Such as the load factor formula in IEC 60076 for rapid transformer capacity estimation.

5. Application of Evaluation Results

Capacity Selection

Determines transformer capacity based on load rate (e.g., 80% design margin) and overloading capability (e.g., 1.5× rated current for 2 hours).

Loss Distribution

Iron losses (PFe) are load-independent, while copper losses (PCu) scale with load squared, necessitating a balance between no-load and load losses.

Temperature Rise Control

Calculates winding hot-spot temperatures based on load characteristics to ensure compliance with insulation material thermal ratings (e.g., Class A ≤105°C).

Conclusion

Load characteristic evaluation must integrate load type, temporal dynamics, and environmental coupling using measurement, simulation, and empirical methods to build a refined model. The results directly impact capacity selection, loss distribution, and operational reliability, forming the foundation of distribution transformer design.