General Methods for Fuel Analysis I: Analysis of Elements and Nonhydrocarbon Compounds

Q4 Energy

Paliva Pub Date : 2023-06-30 DOI:10.35933/paliva.2023.02.01

Martin Staš, P. Baroš, L. Matějovský, H. Kittel, P. Šimáček

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Abstract

This article is the first in a series of articles aimed at introducing common methods for evaluating gaseous, liquid, and solid conventional and alternative fuels. The paper presents an overview of the monitored elements and their non-hydrocarbon compounds for individual liquid and gaseous fuels. Methods for determining these analytes are also presented. The significance of these determinations is also discussed. The emphasis is given mainly on standardized parameters and tests, but in some cases, we discuss also non-standardized tests or analyses not required by standards. The main goal of the article is to provide a comprehensive overview of elements and their non-hydrocarbon compounds monitored for individual fuels, the reason why these analytes are monitored, and what methods are used for this monitoring. Practically all liquid fuels discussed in this article are monitored for sulfur content. The limit value for sulfur content is 10 mg/kg, with the exception of paraffinic diesel fuel and some synthetic liquid fuels. Phosphorus content is monitored in all fuels containing a higher proportion of biocomponents. Examples such fuels are ethanol, FAME, E85, E95, and rapeseed oil. For fuels containing ethanol, the oxygen content (E5, E10) and alcohol content (E5, E10, E85 and E95), or ether content (E5, E10, E85) are also monitored. Among the minor elements, lead (E5, E10, E95), manganese (E5, E10, B7, and B10), copper (ethanol, E95), alkali metals (FAME) and alkaline earth metals (FAME and rape oil) are monitored. As with liquid fuels, the sulfur content of gaseous fuels is also monitored. Of the sulfur compounds, the sum of sulfur and carbonyl sulfide content is monitored for CNG, LNG, and their bioequivalents. For LPG for internal combustion engines, sulfane is determined qualitatively, whereas for LPG for heating purposes, the sulfur content is quantified. In the case of LPG for heating purposes, the ammonia content is determined qualitatively, and in the case of biogas according to ČSN 65 6514, the content of nitrogenous impurities except to nitrogen, and the sum of the content of carbon dioxide, nitrogen and oxygen are also evaluated.

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燃料分析的一般方法1:元素和非碳氢化合物的分析

本文是系列文章的第一篇，旨在介绍评估气体、液体和固体常规燃料和替代燃料的常用方法。本文概述了单个液体和气体燃料的监测元素及其非烃化合物。还介绍了测定这些分析物的方法。本文还讨论了这些决定的意义。重点主要是标准化参数和测试，但在某些情况下，我们也讨论非标准化测试或标准不要求的分析。本文的主要目标是提供对单个燃料监测的元素及其非碳氢化合物的全面概述，这些分析物被监测的原因，以及用于这种监测的方法。实际上，本文讨论的所有液体燃料都监测其硫含量。除石蜡柴油和部分合成液体燃料外，硫含量限值为10mg /kg。对所有含有较高比例生物成分的燃料的磷含量进行监测。这类燃料有乙醇、FAME、E85、E95和菜籽油。对于含乙醇的燃料，还监测氧含量(E5、E10)和酒精含量(E5、E10、E85、E95)或醚含量(E5、E10、E85)。微量元素有铅(E5、E10、E95)、锰(E5、E10、B7、B10)、铜(乙醇、E95)、碱金属(FAME)、碱土金属(FAME、菜籽油)等。与液体燃料一样，气态燃料的硫含量也受到监测。在含硫化合物中，监测CNG、LNG及其生物等价物的硫和羰基硫化物含量之和。对于用于内燃机的液化石油气，硫化物是定性测定的，而用于加热目的的液化石油气，硫含量是定量测定的。在用于加热目的的液化石油气的情况下，定性地确定氨的含量，而在沼气的情况下，根据ČSN 65 6514，除氮外的含氮杂质的含量，以及二氧化碳、氮和氧的含量的总和也进行了评估。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Paliva Earth and Planetary Sciences-Geotechnical Engineering and Engineering Geology

CiteScore

0.50

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0.00%

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