针对真实驾驶条件的自动发动机校准验证

Q3 Engineering

International Journal of Powertrains Pub Date : 2020-10-26 DOI:10.1504/ijpt.2020.10033157

T. Fletcher, N. Kalantzis, M. Cary, Bob Lygoe, Antonios Pezouvanis, K. Ebrahimi

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引用次数: 0

摘要

随着WLTP和RDE测试的引入，汽车制造商必须验证其车辆在各种操作条件下的可靠和高效运行。尽管可变凸轮正时(VCT)、废气再循环(EGR)和强制感应等技术会带来干扰，但发动机的空气增压控制和扭矩传递应该是一致的、平稳的和可预测的。这对于需要精确控制发动机扭矩的混合动力和adas车辆尤为重要。验证是一个迭代过程，可能非常耗时、昂贵，并且需要相当多的经验才能满足验证标准。本文介绍了在英国福特敦顿技术中心引入的自动验证过程。自动化程序已被证明可将验证过程时间减少约50%，从而显着节省成本，同时将校准的总体准确性提高约30-50%。

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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Automated engine calibration validation for real world driving conditions

With the introduction of the WLTP and RDE tests, it has become imperative for automotive manufacturers to verify that their vehicles operate reliably and efficiently across a wide range of operating conditions. Engine air-charge control and torque delivery should be consistent, smooth, and predictable, despite disturbances induced by technologies such as variable cam timing (VCT), exhaust gas recirculation (EGR) and forced induction. This is of particular importance to hybrid and ADAS-enabled vehicles which require accurate control of the engine torque. The validation is an iterative process which can be very time-consuming, expensive and requires considerable experience in order to meet validation criteria. This paper describes the introduction of an automated validation process at the Ford's Dunton Technical Centre in the UK. The automated procedure has been shown to reduce validation process time by around 50% resulting in significant cost-saving whilst improving the overall accuracy of the calibration by around 30-50%.

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来源期刊

International Journal of Powertrains Engineering-Automotive Engineering

CiteScore

1.20

自引率

0.00%

发文量

期刊介绍： IJPT addresses novel scientific/technological results contributing to advancing powertrain technology, from components/subsystems to system integration/controls. Focus is primarily but not exclusively on ground vehicle applications. IJPT''s perspective is largely inspired by the fact that many innovations in powertrain advancement are only possible due to synergies between mechanical design, mechanisms, mechatronics, controls, networking system integration, etc. The science behind these is characterised by physical phenomena across the range of physics (multiphysics) and scale of motion (multiscale) governing the behaviour of components/subsystems.