基于道路行驶工况辨识的重型载货汽车排气制动系统主动控制研究

doi:10.19562/j.chinasae.qcgc.2023.01.012

Abstract

Abstract:

For the problem of improper use of the service brake system due to unfamiliarity of the driver with the road conditions of heavy truck driving on long downhill sections， which leads to the risk of brake thermal degradation， this paper proposes an active control strategy of the exhaust brake system of heavy-duty trucks based on the identification of road driving conditions. Considering the difficulty of accurately obtaining the longitudinal gradient information of the road in mountainous areas and different characteristics of brake pedal action compared with other road sections， this paper selects the average brake pedal opening range in the time window， the continuous working time and the ratio of the brake pedal working time to construct the driving braking conditions on downhill sections and other road braking conditions. Then the hidden Markov model with continuous time series characteristics， including time window lengths of 30， 60， 90 and 120 s， are established by the causal relationship between the brake pedal action and the opening of the exhaust brake system. And off-line training and on-line identification verification are carried out using the test data of K25-K174 in the Ya’an-Xichang section of Jingkun Expressway. The road test and simulation results show that the control strategy proposed in this paper can accurately identify the driving conditions of the vehicle， realize the active control of the exhaust brake system， reduce the high dependence on the driver， and improve the driving safety of heavy-duty trucks on downhill sections.

Key words: automotive engineering, heavy-duty truck, driving cycle, hidden Markov model, active control

Peilong Shi,Xuan Zhao,Zitong Chen,Qiang Yu. Study on Active Control of Exhaust Brake System for Heavy-duty Truck Based on Road Driving Condition Recognition[J].Automotive Engineering, 2023, 45(1): 104-111.

Figures/Tables 11

References 24

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路段	桩号	制动次数	制动总时长/s	行驶时间/s
右线	K30-K58	1	48	1 852
	K58-K73	35	478	893
	K73-K 87	43	567.9	810
	K87- K174	57	430	6 253
左线	K174+240-k151+810	81	2 165.4	1 441
	K148+770-K115+200	126	1 537	2 097
	K115+200-K72	26	112	2 410
	K72-K58	0	0	874
	K58+810-K28+570	92	1 231	1 946

工况		制动器作用总时间/s	作用次数	排气制动启动次数	温度变化/℃
工况		制动器作用总时间/s	作用次数	排气制动启动次数	2轴	3轴	4轴	6轴
发动机制动		360.0	1	0	30.39	36.77	40.63	62.54
排气制动手动		79.0	15	1	17.16	26.41	20.56	24.12
排气制动主动控制	30 s	165.8	11	1	21.15	28.48	24.57	31.80
	60 s	199.4	12	1	21.50	26.63	24.87	31.80
	90 s	195.2	11	1	21.15	28.48	24.57	32.38
	120 s	226.7	14	1	22.94	29.26	26.29	35.10

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Study on Active Control of Exhaust Brake System for Heavy-duty Truck Based on Road Driving Condition Recognition

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