销售点POS机石油产品掺假检测

O. Ejofodomi, G. Ofualagba, D. Onyishi
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引用次数: 0

摘要

在石油和天然气行业,优质汽油(PMS)、车用汽油(AGO)和两用煤油(DPK)之间的价格差异,经常导致营销商为了赚钱而掺假这些石油产品。掺假是指非法将外来的不良物质引入基材,从而影响基材的质量。在销售点(POS)终端很难检测到石油产品的掺假。目前的掺假检测方法耗时长,需要专门的设备和经验丰富的技术人员来操作,并且不能在POS终端使用。气态蒸汽技术(GVE)是一种创新的掺假检测技术,可用于POS终端,本研究中使用的PePVEAT设备是第一个对石油产品进行GVE的便携式电子设备。使用PePVEAT对从尼日利亚国家石油公司(NNPC)获得的1 L PMS、AGO和DPK纯样品进行GVE检测。对AGO、PMS和DPK的GVE分析结果表明,三种石油产品在GVE过程中表现出独特且不同的化学特征。AGO的峰值排放在测试开始后10-20秒,DPK的峰值排放在测试开始后10-30秒,PMS的峰值排放在测试开始后50-70秒。AGO排放的甲烷为17.52-46.58 ppm,液化石油气为5.35-11.93 ppm,丁烷为35.51-84.6 ppm,甲苯为10.38-69.86 ppm。PMS排放的甲烷为92,063.67-152,168.18 ppm, LPG为301.035-573.61 ppm,丁烷为2210.89-3424.94 ppm,甲苯为1983.02-7187.29 ppm。DPK排放的甲烷为27.13-62.14 ppm, LPG为20.2-74.1 ppm,丁烷为120.41-1635.85 ppm,甲苯为1159.75- 1633.09 ppm。这些排放时间和浓度的变化表明,GVE可以用来检测和区分AGO、PMS和DPK。对AGO、PMS和DPK的GVE分析结果表明,由于PMS、AGO和DPK在GVE过程中都有独特的化学排放,正如本文所证明的那样,GVE可以用于检测PMS与AGO的掺假以及AGO与DPK的掺假。未来的工作包括研究GVE检测AGO掺假PMS、DPK掺假AGO、DPK掺假PMS、AGO掺假DPK和PMS掺假DPK的能力。还将检查使用GVE技术可以检测到的掺假程度和百分比。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Adulteration Detection of Petroleum Products at Point of Sale POS Terminals
In the Oil and Gas Industry, price disparity between Premium Motor Spirit (PMS), Automotive Gas Oil (AGO), and Dual Purpose Kerosene (DPK), often leads to adulteration of these petroleum products by marketers for monetary gains. Adulteration is the illegal introduction of a foreign undesirable substance to a substrate which affects the quality of the substrate. Adulteration of petroleum products are difficult to detect at Point of Sale (POS) terminals. Current methods for adulteration detection are time-consuming, require specialized equipment and experienced technicians to operate them, and cannot be used at POS terminals. Gaseous Vapor Technique (GVE) is an innovative adulteration detection technique that can be employed at POS terminals and the PePVEAT device utilized in this study is the first portable electronic device that performs GVE on petroleum products. GVE testing was performed on pure 1 L samples of PMS, AGO, and DPK obtained from the Nigerian National Petroleum Corporation (NNPC) using PePVEAT. The results obtained from GVE analysis of AGO, PMS, and DPK showed that the three petroleum products exhibited unique and varying chemical characteristics during GVE. AGO gives off its peak emissions between 10-20 seconds from test onset, DPK gives off its peak emissions between 10-30 seconds from test onset, and PMS gives off its peak emissions between 50-70 seconds from test onset. AGO emits 17.52-46.58 ppm of methane, 5.35-11.93 ppm of LPG, 35.51-84.6 ppm of butane, and 10.38-69.86 ppm of toluene. PMS emits 92,063.67-152,168.18 ppm of methane, 301.035-573.61 ppm of LPG, 2210.89-3424.94 ppm of butane, and 1983.02-7187.29 ppm of toluene. DPK emits 27.13-62.14 ppm of methane, 20.2-74.1 ppm of LPG, 120.41-1635.85 ppm of butane, and 1159.75- 1633.09 ppm of toluene. These variations in timing and concentrations of emissions shows that GVE can be utilized to detect and distinguish between AGO, PMS and DPK. The results obtained from GVE analysis of AGO, PMS, and DPK showed that Since PMS, AGO and DPK, each have unique chemical emissions during GVE, as was demonstrated in this paper, it is possible that GVE can be utilized to detect the adulterations of PMS with AGO and the adulteration of AGO with DPK. Future work involves investigating the ability of GVE to detect AGO-adulterated PMS, DPK-adulterated AGO, DPK-adulterated PMS, AGO-adulterated DPK,and PMS-adulterated DPK. The degree and percentage of adulteration that can be detected using the GVE technique will also be examined.
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