BS ISO 6249:2021 - Petroleum Products: Determination of Thermal Oxidation Stability of Gas Turbine Fuels

Standard Number: BS ISO 6249:2021

Pages: 42

Release Date: April 26, 2021

ISBN: 978 0 539 01957 5

Status: Standard

Overview

The BS ISO 6249:2021 is a comprehensive standard that provides a detailed methodology for determining the thermal oxidation stability of gas turbine fuels. This standard is essential for professionals in the petroleum industry, particularly those involved in the production, testing, and quality assurance of gas turbine fuels. With its release in 2021, it reflects the latest advancements and best practices in the field.

Why Thermal Oxidation Stability Matters

Thermal oxidation stability is a critical property of gas turbine fuels, as it affects the performance and longevity of gas turbines. Poor thermal oxidation stability can lead to the formation of deposits and other degradation products that can impair fuel system components, reduce efficiency, and increase maintenance costs. By adhering to the guidelines set forth in BS ISO 6249:2021, manufacturers and users can ensure that their fuels meet the necessary stability requirements, thereby enhancing the reliability and performance of gas turbines.

Key Features of BS ISO 6249:2021

• Comprehensive Methodology: The standard outlines a detailed procedure for assessing the thermal oxidation stability of gas turbine fuels, ensuring accurate and consistent results.
• Industry Relevance: Tailored for professionals in the petroleum sector, this standard is crucial for maintaining high-quality fuel production and testing processes.
• Up-to-Date Information: Released in 2021, the standard incorporates the latest research and technological advancements in the field.
• Global Applicability: As an ISO standard, it is recognized and applicable worldwide, facilitating international trade and cooperation.

Who Should Use This Standard?

The BS ISO 6249:2021 is indispensable for a wide range of professionals, including:

• Fuel Manufacturers: To ensure their products meet international quality and stability standards.
• Quality Assurance Teams: For implementing rigorous testing protocols and maintaining product integrity.
• Research and Development Scientists: To stay abreast of the latest methodologies and improve fuel formulations.
• Regulatory Bodies: For setting compliance benchmarks and ensuring industry standards are met.

Benefits of Implementing BS ISO 6249:2021

Adopting the BS ISO 6249:2021 standard offers numerous benefits, including:

• Enhanced Fuel Performance: By ensuring thermal oxidation stability, fuels can perform more efficiently and reliably.
• Reduced Maintenance Costs: Stable fuels minimize deposit formation, reducing wear and tear on turbine components.
• Improved Safety: Consistent fuel quality reduces the risk of operational failures and accidents.
• Competitive Advantage: Compliance with international standards can enhance a company's reputation and marketability.

Conclusion

The BS ISO 6249:2021 standard is a vital resource for anyone involved in the production, testing, and regulation of gas turbine fuels. By providing a robust framework for assessing thermal oxidation stability, it helps ensure that fuels meet the highest quality standards, thereby supporting the efficient and safe operation of gas turbines. Whether you are a manufacturer, quality assurance professional, or regulatory body, this standard is an essential tool for achieving excellence in the petroleum industry.

BS ISO 6249:2021

This standard BS ISO 6249:2021 Petroleum products. Determination of thermal oxidation stability of gas turbine fuels is classified in these ICS categories:

• 75.160.20 Liquid fuels

This document specifies a procedure for rating the tendencies of gas turbine fuels to deposit decomposition products within the fuel system. It is applicable to middle distillate and wide-cut fuels and is particularly specified for the performance of aviation gas turbine fuels.

The test results are indicative of fuel thermal oxidation stability during gas turbine operation and can be used to assess the level of deposits that form when liquid fuel contacts a heated surface at a specified temperature.

This method is also applicable to aviation turbine fuel that consists of conventional and synthetic blending components as defined in the scope of for instance ASTM D7566^{[ 1]} and Def Stan 91-091^{[ 2]}.