PD IEC TR 63228:2019 - Measurement Protocols for Photovoltaic Devices

Discover the comprehensive guide to the measurement protocols for photovoltaic devices based on organic, dye-sensitized, or perovskite materials with the PD IEC TR 63228:2019 standard. This essential document is a must-have for professionals and researchers in the field of photovoltaic technology, providing detailed methodologies and protocols to ensure accurate and reliable measurements.

Overview

The PD IEC TR 63228:2019 standard is a technical report that outlines the measurement protocols for photovoltaic devices that utilize cutting-edge materials such as organic compounds, dye-sensitized cells, and perovskite structures. Released on July 23, 2019, this document is a critical resource for anyone involved in the development, testing, and implementation of these advanced photovoltaic technologies.

Key Features

• Standard Number: PD IEC TR 63228:2019
• Pages: 38
• Release Date: 2019-07-23
• ISBN: 978 0 539 02931 4
• Status: Standard

Why Choose PD IEC TR 63228:2019?

As the photovoltaic industry continues to evolve, the need for standardized measurement protocols becomes increasingly important. The PD IEC TR 63228:2019 standard provides a robust framework for ensuring that photovoltaic devices are tested and evaluated consistently, leading to more reliable and comparable results across different studies and applications.

Whether you are a researcher, engineer, or manufacturer, this standard offers invaluable insights into the best practices for measuring the performance and efficiency of photovoltaic devices. By adhering to these protocols, you can enhance the credibility of your work and contribute to the advancement of photovoltaic technology.

Applications

The measurement protocols outlined in this standard are applicable to a wide range of photovoltaic devices, including:

• Organic Photovoltaic Devices: These devices utilize organic materials to convert sunlight into electricity, offering flexibility and potential for low-cost production.
• Dye-Sensitized Solar Cells (DSSCs): Known for their aesthetic appeal and ability to perform well in low-light conditions, DSSCs are a popular choice for various applications.
• Perovskite Solar Cells: With their high efficiency and ease of fabrication, perovskite solar cells are at the forefront of photovoltaic research and development.

Benefits of Using PD IEC TR 63228:2019

By implementing the measurement protocols from this standard, you can achieve several benefits, including:

• Consistency: Ensure that your measurement processes are consistent with industry standards, leading to more reliable and comparable results.
• Accuracy: Gain confidence in the accuracy of your measurements, which is crucial for evaluating the performance of photovoltaic devices.
• Credibility: Enhance the credibility of your research and development efforts by adhering to internationally recognized standards.
• Innovation: Stay at the cutting edge of photovoltaic technology by utilizing the latest measurement protocols for emerging materials.

Who Should Use This Standard?

The PD IEC TR 63228:2019 standard is designed for a wide range of professionals and organizations involved in the photovoltaic industry, including:

• Researchers: Academic and industrial researchers focused on developing new photovoltaic materials and technologies.
• Engineers: Professionals responsible for designing and testing photovoltaic devices and systems.
• Manufacturers: Companies involved in the production and quality assurance of photovoltaic products.
• Testing Laboratories: Facilities that conduct performance evaluations and certifications for photovoltaic devices.

Conclusion

The PD IEC TR 63228:2019 standard is an indispensable resource for anyone involved in the field of photovoltaic technology. By providing detailed measurement protocols for devices based on organic, dye-sensitized, or perovskite materials, this standard ensures that your work is aligned with the latest industry practices and standards.

Embrace the future of photovoltaic technology with confidence by utilizing the PD IEC TR 63228:2019 standard. Whether you are conducting research, developing new products, or ensuring quality control, this document will guide you in achieving accurate and reliable results.

PD IEC TR 63228:2019

This standard PD IEC TR 63228:2019 Measurement protocols for photovoltaic devices based on organic, dye-sensitized or perovskite materials is classified in these ICS categories:

• 27.160 Solar energy engineering

This Technical Report summarises present perspectives on the performance evaluation of emerging PV technologies, specifically OPV, DSC and PSC devices. These devices present some challenges for accurate measurement under the existing IEC 60904 series of standards, which were developed in the context of silicon wafer solar cells. These challenges can be different for different devices, but in general they arise due to one or more of the following: instability in performance over time; unusual spectral responsivity; small device size; difficulty in measuring temperature; a transient response to external stimulus; optical interference effects; and a non-linear current response to irradiance. These challenges can lead to the cell output in laboratory testing being significantly different to the output that would be observed in a real application.

The primary focus of the report is measurement of the current-voltage (I-V) relationship under illumination for the purpose of determining the device output power, or power conversion efficiency. Where appropriate, the report makes reference to the IEC 60904 series which describes the standard approach to measuring the performance of all PV devices. The report also references existing published standards that seek to accommodate OPV, DSC or PSC devices.

The report does not seek to find consensus on measurement protocols at this stage. A lot of work has been done by the community toward that aim, but more work is needed. The report therefore seeks to document current knowledge and practices, hence serving as a reference and a tool for conducting further discussion. It is hoped that by identifying the issues that remain unresolved, the report will focus efforts toward resolving those issues, such that a guiding Technical Specification can be prepared in the near future. A robust Technical Specification will bring clarity and confidence to the markets for these PV products as they develop.