Abstract
The knock phenomenon is one of the major hindrances for enhancing the thermal efficiency in spark-ignited engines. Due to the stochastic behavior of knocking combustion, analytical cycle studies are required. However, there are many problems to be addressed with regard to the individual cycle analysis of in-cylinder pressure data. This study thus proposes novel, comprehensive and efficient methodologies for evaluating the knocking combustion in the internal combustion engine. The proposed methodologies include a filtering method for the in-cylinder pressure, the determination of the knock onset, and the calculation of the residual gas fraction. Consequently, a smart knock onset model with high accuracy could be developed using a supervised deep learning that was not available in the past. Moreover, an improved zero-dimensional (0D) estimation model for the residual gas fraction was developed to obtain better accuracy for closed system analysis. Finally, based on a cyclic analysis, a knock prediction model is suggested; the model uses 0D ignition delay correlation under various experimental conditions including aggressive cam phase shifting by a dual variable valve timing (VVT) system. Using the proposed analysis method, insight into stochastic knocking combustion can be obtained, and a faster combustion speed can lead to a higher knock intensity in a steady-state operation.
Highlights
In a spark-ignited (SI) engine, increasing the compression ratio is one of the most promising methods to enhance the indicated thermal efficiency (ITE) [1]
The engine operation in such conditions is accompanied by increases in the pressure and temperature of the unburned gas region, which results in autoignition or knock phenomena [2]
Proper control has a great potential for appropriate knock avoidance with a smaller deterioration of the efficiency, and it may allow the utilization of deflagration to enhance the ITE thanks to the instantaneous consumption of the unburned air-fuel mixture
Summary
In a spark-ignited (SI) engine, increasing the compression ratio is one of the most promising methods to enhance the indicated thermal efficiency (ITE) [1]. The engine operation in such conditions is accompanied by increases in the pressure and temperature of the unburned gas region, which results in autoignition or knock phenomena [2]. Proper control has a great potential for appropriate knock avoidance with a smaller deterioration of the efficiency, and it may allow the utilization of deflagration to enhance the ITE thanks to the instantaneous consumption of the unburned air-fuel mixture. The control has to rely on the instantaneous data, which has to be based on an individual cycle analysis with a proper estimation of the in-cylinder pressure. Insight into knocking combustion will be presented, based on an established cyclic analysis and knock prediction model
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