BBA Steady-State Solar Simulator

The BBA Steady-State Solar Simulator is a high-precision photovoltaic testing system designed to provide stable and standardized solar illumination for full-size PV module evaluation. Using a BBA-class large-area steady-state light source, it accurately simulates natural sunlight conditions for measuring photovoltaic electrical performance, reliability, and aging characteristics. The system supports maximum power testing, temperature coefficient evaluation, low irradiance performance analysis, hotspot durability testing, and light-induced degradation assessment, making it an ideal solution for PV manufacturers, research institutions, and certification laboratories.
Application
The BBA Steady-State Solar Simulator is widely used in photovoltaic research, production testing, and reliability evaluation, including:
(1) PV Module Factory Performance Testing
Used for production quality control, module grading, and electrical performance verification before shipment.
(2) Photovoltaic R&D Evaluation
Supports research on module efficiency, maximum power output, electrical characteristics, and new photovoltaic technologies.
(3) PV Module Aging and Reliability Testing
Used to evaluate light-induced degradation (LID), long-term stability, and performance changes under controlled illumination.
(4) Hotspot Durability Testing
Provides stable solar radiation conditions for analyzing module resistance against hotspot effects and localized heating.
(5) Temperature Coefficient Measurement
Used to evaluate PV module output variation under different temperature conditions.
(6) Low Irradiance Performance Testing
Simulates weak-light environments to analyze photovoltaic performance under reduced solar intensity.
(7) Climate and Environmental Simulation Laboratories
Provides repeatable solar conditions for controlled photovoltaic experiments.
Standards
(1) IEC 60904-6 – Photovoltaic Devices: Procedures for Using Reference Cells and Reference Modules
(2) IEC 61215 – Terrestrial Photovoltaic (PV) Modules: Design Qualification and Type Approval
(3) IEC 61646 – Thin-Film Terrestrial Photovoltaic (PV) Modules: Design Qualification
(4) GB/T 6495.3 – Solar Radiation: Measurement of Spectral Irradiance Distribution
(5) IEC 60904 Series – Photovoltaic Device Measurement Standards
Parameters
| Item | Technical Specification |
|---|---|
| Effective Test Area | 2.0 × 1.0 m |
| Simulator Class | BBA |
| Spectral Match | Class B |
| Irradiance Uniformity | Class B |
| Instantaneous Instability | Class A |
| Light Source Type | Metal halide lamp |
| Measurable Parameters | NOCT, STC, Hot Spot |
| Light Source Lifetime | Approx. 1000 hours per lamp, one spare set included |
| Illumination Direction | Top-down vertical incidence |
| Consumables Lifetime | Light source and filters for approximately 2000 hours |
| Light Intensity Range | 800–1000 W/m² continuously adjustable |
| Low Irradiance Testing | Down to 200 W/m² |
| Operating Temperature | +15°C to +30°C |
| Power Supply | 380V, 50Hz, ≤150A |
| Software Language | Simplified Chinese / Traditional Chinese / English |
| Data Functions | Storage, query, export, printing, Word/Excel/PDF/JPG report output |
Features
(1) Large-Area BBA-Class Solar Simulation
Provides uniform illumination across full-size photovoltaic modules for accurate performance evaluation.
(2) Stable Steady-State Light Output
Maintains consistent solar radiation conditions for repeatable electrical performance testing.
(3) Comprehensive PV Performance Evaluation
Supports STC, NOCT, hotspot durability, temperature coefficient, and light-induced degradation tests.
(4) Precise Irradiance Adjustment
Allows continuous adjustment of solar intensity and supports low irradiance testing for expanded evaluation conditions.
(5) Reliable Optical System
Metal halide light source and optical filters ensure stable spectral characteristics and illumination quality.
(6) Integrated Data Management System
Provides complete data acquisition, storage, analysis, and report generation functions.
(7) Long-Term Operation Capability
Equipped with spare consumable components to reduce downtime during continuous laboratory testing.
FAQ
(1) What is the primary purpose of the BBA Steady-State Solar Simulator?
The BBA Steady-State Solar Simulator is designed to reproduce controlled solar conditions for photovoltaic module testing. It is used to evaluate maximum power output, efficiency, temperature coefficient, hotspot durability, low irradiance performance, and light-induced degradation, providing reliable testing conditions for PV research, production inspection, and certification.
(2) What types of photovoltaic tests can be performed with this simulator?
This system supports multiple PV module evaluation methods, including STC performance testing, NOCT testing, I-V curve measurement, hotspot durability analysis, temperature coefficient measurement, and light-induced degradation testing. It is suitable for crystalline silicon modules, thin-film modules, and advanced photovoltaic technologies.
(3) Can the BBA Steady-State Solar Simulator test full-size PV modules?
Yes. With an effective test area of 2.0 × 1.0 m, the system is designed for full-size photovoltaic module testing. Its BBA-class illumination performance provides stable and uniform solar conditions across the module surface, ensuring accurate electrical performance measurement.
(4) How does the simulator ensure testing accuracy and repeatability?
The system combines controlled metal halide illumination, optical filters, irradiance adjustment, and calibration functions to maintain stable solar conditions. Regular calibration and data management ensure consistent results during repeated photovoltaic performance evaluations.
(5) How to choose the right solar simulator for PV module testing?
When selecting a solar simulator, users should consider the PV module size, required simulator classification, testing standards, application purpose, and required measurement functions. For certification and laboratory testing, spectral matching, uniformity, and stability are key factors. For production quality control, test efficiency, automation capability, data management, and long-term operating reliability should also be considered.
For customized photovoltaic testing solutions, please contact our technical team for professional recommendations.
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