0D Modeling of Fuel Tank for Vapor Generation

L. Romagnuolo, A. Andreozzi, A. Senatore, E. Frosina, F. Fortunato, Vincenzo G. Mirante
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Abstract

Petrol vapor emissions are the main source of pollution for both standard and hybrid vehicles. They are mainly generated by gasoline evaporation from the fuel tank of both running and parked vehicles; it is mostly driven by fuel temperature variation due to daily temperature changes (if parked) and heat from engine (if running). To prevent its dispersion in the environment, the vapor generated in the fuel tank is usually stored in a carbon canister filter that must be periodically “purged” in order to prevent its saturation, by venting it to the intake manifold. Canister management, made by the Engine Control Unit (ECU), becomes even more critical for hybrid-electric vehicles because thermal engine is often off, thus purging cannot take place. A pressurized fuel tank is often used for hybrid applications, to further isolate vapor from environment, making the fuel system even more complex to model. System design optimization is usually based on experience and experimental correlations, which require time and cost. Thus, comes the need for a comprehensive predictive model useful for both vehicle components (fuel tank and carbon canister) and ECU software design. A 0D Matlab® model is proposed, which can predict vapor generation from an arbitrary tank in standard and arbitrary thermal cycles, with arbitrary tank capacity, geometry and construction and at different filling levels. It is based on a system of thermo-fluid-dynamic differential equations and semi-empirical correlations that is iteratively solved in time. Model calibration has been performed by using a small size test tank and validation has been completed on full size tanks for both standard and hybrid-electric applications. The main driving force for vapor generation has been shown to be the amount of empty volume on top of the tank; other significant effects come from tank volume, material, external surface as well as fuel properties. Ongoing work is to develop and integrate a carbon canister loading/purging model, with the aim to build a full model of the vapor system.
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油箱蒸汽生成的三维建模
汽油蒸气排放是标准和混合动力汽车的主要污染源。它们主要是由行驶车辆和停放车辆油箱的汽油蒸发产生的;它主要是由日常温度变化引起的燃料温度变化(如果停车)和发动机的热量(如果运行)驱动的。为了防止其在环境中分散,油箱中产生的蒸汽通常存储在碳罐过滤器中,必须定期“净化”,以防止其饱和,通过将其排放到进气歧管。由于热发动机经常处于关闭状态,因此无法进行净化,因此由发动机控制单元(ECU)进行的气罐管理对混合动力汽车来说变得更加重要。增压油箱通常用于混合动力应用,以进一步隔离蒸汽与环境,使燃料系统更加复杂的模型。系统设计优化通常基于经验和实验相关性,这需要时间和成本。因此,需要一个对车辆部件(油箱和碳罐)和ECU软件设计都有用的综合预测模型。提出了一个0D Matlab®模型,该模型可以预测任意罐在标准和任意热循环下,在任意罐容量,几何形状和结构以及不同填充水平下的蒸汽生成。它是基于一个系统的热流体动力学微分方程和半经验的相关性,是迭代求解的时间。通过使用小尺寸测试罐进行了模型校准,并在标准和混合动力应用的全尺寸罐上完成了验证。蒸汽产生的主要驱动力已被证明是罐顶的空容积量;其他重要的影响来自油箱容积、材料、外表面以及燃料特性。正在进行的工作是开发和整合碳罐装载/净化模型,目的是建立一个完整的蒸汽系统模型。
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