BS EN ISO 21683:2020 - Pigments and Extenders: Determination of Experimentally Simulated Nano-Object Release

In the ever-evolving world of materials science and engineering, understanding the behavior of nano-objects in various applications is crucial. The BS EN ISO 21683:2020 standard provides a comprehensive framework for the determination of experimentally simulated nano-object release from paints, varnishes, and pigmented plastics. This standard is an essential tool for professionals in the field of materials science, coatings, and environmental safety.

Overview of the Standard

The BS EN ISO 21683:2020 standard is a meticulously crafted document that outlines the procedures and methodologies for assessing the release of nano-objects from various pigmented materials. Released on October 1, 2020, this standard is a testament to the ongoing commitment to safety and innovation in the industry. With a total of 28 pages, it provides detailed guidance and insights into the experimental simulation of nano-object release.

Key Features and Benefits

• Comprehensive Guidance: The standard offers a thorough approach to understanding the release mechanisms of nano-objects, ensuring that professionals can accurately assess potential environmental and health impacts.
• Industry Relevance: Applicable to a wide range of industries, including paints, varnishes, and plastics, this standard is crucial for manufacturers and researchers aiming to maintain high safety and quality standards.
• Up-to-Date Information: As a 2020 release, the standard incorporates the latest research and technological advancements, providing users with the most current methodologies and data.
• ISBN Reference: For easy cataloging and reference, the standard is identified by ISBN 978 0 539 13172 7.

Applications and Use Cases

The BS EN ISO 21683:2020 standard is indispensable for a variety of applications, including:

• Research and Development: Scientists and researchers can utilize this standard to explore the behavior of nano-objects in different pigmented materials, leading to innovations in product development.
• Quality Assurance: Manufacturers can implement the guidelines to ensure their products meet safety and quality standards, thereby enhancing consumer trust and satisfaction.
• Environmental Safety: By understanding the release of nano-objects, companies can better assess and mitigate potential environmental impacts, contributing to sustainable practices.

Why Choose BS EN ISO 21683:2020?

Choosing the BS EN ISO 21683:2020 standard means opting for a reliable and authoritative source of information. This standard is recognized globally, ensuring that your practices align with international safety and quality benchmarks. Whether you are a researcher, manufacturer, or environmental safety officer, this standard provides the tools and knowledge necessary to excel in your field.

Conclusion

In conclusion, the BS EN ISO 21683:2020 standard is a vital resource for anyone involved in the production, research, or regulation of pigmented materials. Its comprehensive guidelines and up-to-date methodologies make it an essential addition to any professional library. Embrace the future of materials science with confidence and ensure your practices are at the forefront of safety and innovation.

Note: This standard is currently active and available for implementation in relevant industries.

BS EN ISO 21683:2020

This standard BS EN ISO 21683:2020 Pigments and extenders. Determination of experimentally simulated nano-object release from paints, varnishes and pigmented plastics is classified in these ICS categories:

• 87.060.10 Pigments and extenders

This document specifies a method for experimental determination of the release of nanoscale pigments and extenders into the environment following a mechanical stress of paints, varnishes and pigmented plastics.

The method is used to evaluate if and how many particles of defined size and distribution under stress (type and height of applied energy) are released from surfaces and emitted into the environment.

The samples are aged, weathered or otherwise conditioned to simulate the whole lifecycle.