BS EN IEC 60904-9:2020 - Photovoltaic Devices Classification of Solar Simulator Characteristics

Welcome to the comprehensive guide on the BS EN IEC 60904-9:2020 standard, a pivotal document for professionals in the photovoltaic industry. This standard is essential for anyone involved in the design, testing, and implementation of solar simulators, providing a detailed classification of their characteristics. Released on November 11, 2020, this document is a must-have for ensuring compliance and excellence in photovoltaic device performance.

Overview of the Standard

The BS EN IEC 60904-9:2020 standard is a critical resource for understanding the classification of solar simulator characteristics. It provides guidelines and specifications that are crucial for the accurate simulation of solar radiation in laboratory settings. This standard is designed to ensure that photovoltaic devices are tested under conditions that closely mimic natural sunlight, thereby guaranteeing the reliability and efficiency of solar energy systems.

Key Features:

• Standard Number: BS EN IEC 60904-9:2020
• Pages: 34
• Release Date: November 11, 2020
• ISBN: 978 0 580 97353 6
• Status: Standard

Importance of Solar Simulator Classification

Solar simulators are indispensable tools in the photovoltaic industry, used to test and evaluate the performance of solar cells and modules. The classification of these simulators, as outlined in the BS EN IEC 60904-9:2020 standard, ensures that they meet specific criteria for spectral match, spatial uniformity, and temporal stability. These parameters are crucial for replicating the conditions of natural sunlight, which is essential for accurate testing and development of photovoltaic technologies.

Benefits of Compliance:

• Accuracy: Ensures that solar simulators provide a precise replication of sunlight, leading to more reliable test results.
• Consistency: Standardized testing conditions allow for consistent and comparable results across different laboratories and testing facilities.
• Quality Assurance: Adhering to the standard helps in maintaining high quality and performance of photovoltaic devices.
• Innovation: Facilitates the development of new technologies by providing a reliable framework for testing and evaluation.

Detailed Insights into the Standard

The BS EN IEC 60904-9:2020 standard is divided into several sections, each focusing on different aspects of solar simulator characteristics. It provides detailed guidelines on the classification of simulators based on their ability to replicate the solar spectrum, their spatial uniformity, and their temporal stability. These classifications are essential for ensuring that photovoltaic devices are tested under conditions that closely resemble real-world scenarios.

Sections of the Standard:

• Spectral Match: This section outlines the requirements for the spectral distribution of the simulator light, ensuring it closely matches the solar spectrum.
• Spatial Uniformity: Details the criteria for uniform light distribution across the test area, which is crucial for accurate device evaluation.
• Temporal Stability: Specifies the stability of the light output over time, ensuring consistent testing conditions.

Who Should Use This Standard?

The BS EN IEC 60904-9:2020 standard is an invaluable resource for a wide range of professionals in the photovoltaic industry, including:

• Researchers and Scientists: Engaged in the development and testing of new photovoltaic technologies.
• Quality Assurance Professionals: Responsible for ensuring the performance and reliability of solar devices.
• Manufacturers: Involved in the production of solar cells and modules, ensuring their products meet industry standards.
• Testing Laboratories: Conducting evaluations and certifications of photovoltaic devices.

Conclusion

In conclusion, the BS EN IEC 60904-9:2020 standard is a cornerstone document for the photovoltaic industry, providing essential guidelines for the classification of solar simulator characteristics. By adhering to this standard, professionals can ensure the accuracy, consistency, and quality of their photovoltaic testing and development processes. Whether you are a researcher, manufacturer, or quality assurance professional, this standard is an indispensable tool for achieving excellence in solar energy technology.

BS EN IEC 60904-9:2020

This standard BS EN IEC 60904-9:2020 Photovoltaic devices is classified in these ICS categories:

• 27.160 Solar energy engineering

IEC 60904-9:2020 is applicable for solar simulators used in PV test and calibration laboratories and in manufacturing lines of solar cells and PV modules. This document define classifications of solar simulators for use in indoor measurements of terrestrial photovoltaic devices. Solar simulators are classified as A+, A, B or C based on criteria of spectral distribution match, irradiance non-uniformity in the test plane and temporal instability of irradiance. This document provides the required methodologies for determining the classification of solar simulators in each of the categories. A solar simulator which does not meet the minimum requirements of class C cannot be classified according to this document. This document is used in combination with IEC TR 60904-14, which deals with best practice recommendations for production line measurements of single-junction PV module maximum power output and reporting at standard test conditions. This third edition cancels and replaces the second edition issued in 2007. This edition includes the following significant technical changes with respect to the previous edition: - Changed title; - Added spectral match classification in an extended wavelength range; - Introduction of new A+ class; - Definition of additional parameters for spectral irradiance evaluation; - Added apparatus sections for spectral irradiance measurement and spatial uniformity measurement; - Revised procedure for spectral match classification (minimum 4 measurement locations); - Revised measurement procedure for spatial uniformity of irradiance; - Added informative Annex for sensitivity analysis of spectral mismatch error related to solar simulator spectral irradiance.