Smart in-cylinder pressure sensor for closed-loop combustion control

IF 0.8 Q4 INSTRUMENTS & INSTRUMENTATION Journal of Sensors and Sensor Systems Pub Date : 2022-01-04 DOI:10.5194/jsss-11-1-2022
Dennis Vollberg, P. Gibson, G. Schultes, Hans-Werner Groh, T. Heinze
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引用次数: 2

Abstract

Abstract. Our approach of a closed-loop combustion control is built on an intensively evaluated robust cylinder pressure sensor with integrated smart electronics and an openly programmed engine control unit. The presented pressure sensor consists of a steel membrane and a highly strain-sensitive thin film with laser-welded electrical contacts. All components are optimized for reliable operation at high temperatures. The sensor setup safely converts the in-cylinder pressure of a combustion engine at temperatures of up to 200 ∘C into the desired electrical values. Furthermore, the embedded smart electronics provides a fast analogue to digital conversion and subsequently computes significant combustion parameters in real time, based on implemented thermodynamic equations, namely the 50 % mass fraction burned, the indicated mean effective pressure, the maximum pressure and a digital value, which represents the intensity of knocking. Only these aggregated parameters – not the running pressure values – are sent to the engine control unit. The data communication between the smart sensor and the engine control unit is based on the controller area network bus system, which is widely spread in the automotive industry and allows a robust data transfer minimizing electrical interferences. The established closed-loop combustion control is able to control the ignition angle in accordance with the 50 % mass fraction burned at a certain crankshaft angle. With this loop, the combustion engine is controlled and run efficiently even if the ignition angle is intentionally incorrectly adjusted. The controlled and automatic correction of simulated ageing effects is demonstrated as well as the self-adjustment of an efficient operation when different fuels are used. In addition, our approach saves the computing capacity of the engine control unit by outsourcing the data processing to the sensor system.
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用于闭环燃烧控制的智能缸内压力传感器
摘要我们的闭环燃烧控制方法建立在经过深入评估的稳健气缸压力传感器上,该传感器具有集成的智能电子设备和开放编程的发动机控制单元。现有的压力传感器由钢膜和具有激光焊接电触点的高度应变敏感薄膜组成。所有部件都经过优化,可在高温下可靠运行。传感器设置可安全地转换高达200的内燃机减温的缸内压力 ∘C转换为所需的电气值。此外,嵌入式智能电子设备提供了快速的模数转换,并随后基于实现的热力学方程实时计算重要的燃烧参数,即50 % 燃烧的质量分数、指示的平均有效压力、最大压力和表示爆震强度的数字值。只有这些汇总参数(而不是运行压力值)被发送到发动机控制单元。智能传感器和发动机控制单元之间的数据通信基于控制器局域网总线系统,该系统在汽车行业中广泛应用,并允许稳健的数据传输,最大限度地减少电气干扰。建立的闭环燃烧控制能够根据50 % 在一定曲轴角度下燃烧的质量分数。有了这个回路,即使点火角度故意调整不正确,内燃机也能得到控制并有效运行。演示了模拟老化效应的受控和自动校正,以及在使用不同燃料时有效操作的自调整。此外,我们的方法通过将数据处理外包给传感器系统来节省发动机控制单元的计算能力。
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来源期刊
Journal of Sensors and Sensor Systems
Journal of Sensors and Sensor Systems INSTRUMENTS & INSTRUMENTATION-
CiteScore
2.30
自引率
10.00%
发文量
26
审稿时长
23 weeks
期刊介绍: Journal of Sensors and Sensor Systems (JSSS) is an international open-access journal dedicated to science, application, and advancement of sensors and sensors as part of measurement systems. The emphasis is on sensor principles and phenomena, measuring systems, sensor technologies, and applications. The goal of JSSS is to provide a platform for scientists and professionals in academia – as well as for developers, engineers, and users – to discuss new developments and advancements in sensors and sensor systems.
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