Nicholas L. Brogaard, Martin X. Sørensen, J. Fritt-Rasmussen, A. Rangwala, G. Jomaas
{"title":"一种新型水上烧油实验装置——原油和纯油实验结果","authors":"Nicholas L. Brogaard, Martin X. Sørensen, J. Fritt-Rasmussen, A. Rangwala, G. Jomaas","doi":"10.3801/iafss.fss.11-1481","DOIUrl":null,"url":null,"abstract":"A new experimental apparatus, the Crude Oil Flammability Apparatus (COFA), has been developed to study in-situ burning of crude and pure oils spilled on water in a controlled laboratory environment with large water-to-oil ratios. The parameters and phenomena studied for an asphaltic crude oil (Grane) and two pure oils (n-Octane and dodecane) with different initial oil layer thicknesses include burning efficiency, burning rate, regression rate, flame height and boilover. Pyrex glass cylinders (157 and 260 mm ID) placed on top of a steel foot in a water basin (1m x 1m x 0.5m) enabled free circulation of the water, which, along with the large water-to-oil ratios (up to 10,000) ensured that the oil burning barely increased the temperature of the surrounding water environment, which created more realistic offshore conditions than seen in many other laboratory studies. The burning efficiency was found to be nearly 100% for n-Octane and of dodecane, whereas the crude oil burning efficiency ranged between 35% and 65%. The main reason for this variation proved to be the onset of an extremely violent boilover, which occurs for oils with relatively high boiling temperatures when the water sub layer is superheated. When the initial crude oil layer thickness exceeded 20 mm the oil became solid and no boilover occurred. The heat-loss to the water sub-layer also had an effect on the burning efficiency and the regression rate was found to reach a constant value after increasing continuously as the oil was heated. Similar results were found regarding the flame height which reached a steady flame height. The pure fuels, n-Octane and dodecane, produced a much higher steady flame height than the crude oil, however they did not reach boilover, though dodecane showed boilover tendencies. Theoretical predictions with existing correlations and input data specific for the current oils generally compared well with the experimental data for both the time to boilover and the regression rates. As such, the COFA is envisioned to produce high-fidelity results in the future and thereby contribute to the further development of in-situ burning as an alternative response technique for oil spills on water.","PeriodicalId":12145,"journal":{"name":"Fire Safety Science","volume":"1 1","pages":"1481-1495"},"PeriodicalIF":0.0000,"publicationDate":"2014-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"18","resultStr":"{\"title\":\"A new Experimental Rig for Oil Burning on Water – Results for Crude and Pure Oils\",\"authors\":\"Nicholas L. Brogaard, Martin X. Sørensen, J. Fritt-Rasmussen, A. Rangwala, G. Jomaas\",\"doi\":\"10.3801/iafss.fss.11-1481\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"A new experimental apparatus, the Crude Oil Flammability Apparatus (COFA), has been developed to study in-situ burning of crude and pure oils spilled on water in a controlled laboratory environment with large water-to-oil ratios. The parameters and phenomena studied for an asphaltic crude oil (Grane) and two pure oils (n-Octane and dodecane) with different initial oil layer thicknesses include burning efficiency, burning rate, regression rate, flame height and boilover. Pyrex glass cylinders (157 and 260 mm ID) placed on top of a steel foot in a water basin (1m x 1m x 0.5m) enabled free circulation of the water, which, along with the large water-to-oil ratios (up to 10,000) ensured that the oil burning barely increased the temperature of the surrounding water environment, which created more realistic offshore conditions than seen in many other laboratory studies. The burning efficiency was found to be nearly 100% for n-Octane and of dodecane, whereas the crude oil burning efficiency ranged between 35% and 65%. The main reason for this variation proved to be the onset of an extremely violent boilover, which occurs for oils with relatively high boiling temperatures when the water sub layer is superheated. When the initial crude oil layer thickness exceeded 20 mm the oil became solid and no boilover occurred. The heat-loss to the water sub-layer also had an effect on the burning efficiency and the regression rate was found to reach a constant value after increasing continuously as the oil was heated. Similar results were found regarding the flame height which reached a steady flame height. The pure fuels, n-Octane and dodecane, produced a much higher steady flame height than the crude oil, however they did not reach boilover, though dodecane showed boilover tendencies. Theoretical predictions with existing correlations and input data specific for the current oils generally compared well with the experimental data for both the time to boilover and the regression rates. 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引用次数: 18
摘要
原油可燃性实验装置(COFA)是一种新型的实验装置,用于研究原油和纯油在大水油比的受控实验室环境中洒在水中的原位燃烧。研究了不同初始油层厚度的沥青原油(Grane)和两种纯油(正辛烷和十二烷)的燃烧效率、燃烧速率、回归速率、火焰高度和沸点over等参数和现象。耐热玻璃圆柱体(内径为157和260毫米)放置在水池(1m x 1m x 0.5m)的钢脚上,使水能够自由循环,这与大的水油比(高达10,000)一起确保了石油燃烧几乎不会增加周围水环境的温度,这创造了比许多其他实验室研究更现实的海上条件。正辛烷和十二烷的燃烧效率接近100%,而原油的燃烧效率在35% ~ 65%之间。这种变化的主要原因被证明是一种极端剧烈的沸腾,当水亚层过热时,这种沸腾温度相对较高的油就会发生。当初始原油层厚度超过20 mm时,原油变为固体,不发生沸翻。水亚层的热损失对燃烧效率也有影响,随着油的加热,回归率不断增大,达到一个恒定值。火焰高度也得到了类似的结果,达到了一个稳定的火焰高度。纯燃料正辛烷和十二烷产生的稳定火焰高度比原油高得多,但它们没有达到沸腾,而十二烷有沸腾的趋势。根据现有相关性和特定于当前油品的输入数据进行的理论预测,在沸翻时间和回归速率方面,通常与实验数据比较良好。因此,预计COFA将在未来产生高保真度的结果,从而有助于进一步发展原位燃烧作为一种替代的应对水上溢油的技术。
A new Experimental Rig for Oil Burning on Water – Results for Crude and Pure Oils
A new experimental apparatus, the Crude Oil Flammability Apparatus (COFA), has been developed to study in-situ burning of crude and pure oils spilled on water in a controlled laboratory environment with large water-to-oil ratios. The parameters and phenomena studied for an asphaltic crude oil (Grane) and two pure oils (n-Octane and dodecane) with different initial oil layer thicknesses include burning efficiency, burning rate, regression rate, flame height and boilover. Pyrex glass cylinders (157 and 260 mm ID) placed on top of a steel foot in a water basin (1m x 1m x 0.5m) enabled free circulation of the water, which, along with the large water-to-oil ratios (up to 10,000) ensured that the oil burning barely increased the temperature of the surrounding water environment, which created more realistic offshore conditions than seen in many other laboratory studies. The burning efficiency was found to be nearly 100% for n-Octane and of dodecane, whereas the crude oil burning efficiency ranged between 35% and 65%. The main reason for this variation proved to be the onset of an extremely violent boilover, which occurs for oils with relatively high boiling temperatures when the water sub layer is superheated. When the initial crude oil layer thickness exceeded 20 mm the oil became solid and no boilover occurred. The heat-loss to the water sub-layer also had an effect on the burning efficiency and the regression rate was found to reach a constant value after increasing continuously as the oil was heated. Similar results were found regarding the flame height which reached a steady flame height. The pure fuels, n-Octane and dodecane, produced a much higher steady flame height than the crude oil, however they did not reach boilover, though dodecane showed boilover tendencies. Theoretical predictions with existing correlations and input data specific for the current oils generally compared well with the experimental data for both the time to boilover and the regression rates. As such, the COFA is envisioned to produce high-fidelity results in the future and thereby contribute to the further development of in-situ burning as an alternative response technique for oil spills on water.