Sage Journals: Discover world-class research

Abstract

Due to the difference in gradient resistance between the front and rear vehicles, the long marshalling train will produce a larger longitudinal impulse when it passes through the gradient change point for blend braking. The conventional strategy of simultaneous application of dynamic and air braking and average distribution of dynamic braking is not necessarily optimal, it is significant to optimize in-train longitudinal forces under the target braking performance through the different blend braking strategy for heavy haul train. Firstly, mathematical models of in-train longitudinal forces are developed for longitudinal train dynamic simulations including the air braking system sub-model with the brake delay time and multi-stages nonlinear charging characteristics and the friction draft gear sub-model with the viscous resistance characteristics. Besides, longitudinal dynamic simulation is conducted to study and analyze the dynamic braking matching strategy in a typical case when “1+1+1” 20,000-ton train passes through the gradient change point of “-12‰ downhill-straight track” for blend braking. The influence of different dynamic braking distribution and asynchronous application strategy on the longitudinal impulse of the train is analyzed. Finally, a particle swarm optimization algorithm is proposed to achieve rapid optimization of the optimal locomotive dynamic braking distribution. This work provides valuable insights into simulating in-train longitudinal forces to realize the safe and efficient operation of heavy haul trains in the future.

Keywords

Heavy haul train longitudinal train dynamic gradient change point blend braking

Get full access to this article

View all access options for this article.

References

Bosso

Magelli

Zampieri

(2023) A numerical method for the simulation of freight train emergency braking operations based on the UIC braked weight percentage. Railway Engineering Science 31(2): 162–171.

CARS (2015) Comprehensive Experiment of 20,000-ton Distributed-Power Train Based on LTE Network in Shuohuang Railway (Final report). Beijing: China Academy of Railway Sciences.

Chen

Liu

Rao

, et al. (2025) Explicit speed-integrated LSTM network for non-stationary gearbox vibration representation and fault detection under varying speed conditions. Reliability Engineering & System Safety 254: 110596.

Cole

(1998) Improvements to wagon connection modelling for longitudinal train simulation. In: CORE 1998 Engineering Innovation for a Competitive Edge Conference on Railway. Queensland, Australia: National Library of Australia, 187–194.

Dong

Zuo

Ding

(2025) Vibration-adaptive energy management technology for self-sufficient wireless ECP braking systems on heavy-haul trains. Mechanical Systems and Signal Processing 223: 111940.

Chang

Wang

, et al. (2024) Analysis on key influencing factors of longitudinal force with 30,000 t heavy haul trains in braking conditions. Journal of the China Railway Society 46(1): 53–59.

Huang

Yang

, et al. (2025) Physics-informed deep learning for virtual rail train trajectory following control. Reliability Engineering & System Safety 261: 111092.

Huang

Zeng

, et al. (2025) A physical‒data-driven combined strategy for load identification of tire type rail transit vehicle. Reliability Engineering & System Safety 253: 110493.

Yao

Zhang

, et al. (2023) Analysis and research of blend braking for longitudinal force optimization of heavy haul combined train. Journal of Railway Science and Engineering 20(2): 694–705.

10.

Liu

Tang

, et al. (2022) Study on longitudinal dynamics of heavy haul trains running on long and steep downhills. Vehicle System Dynamics 60(12): 4079–4097.

11.

Liu

Wang

Liu

, et al. (2024) A heavy-haul train longitudinal-vertical coupled dynamics model and its dynamic behaviour under emergency braking. Vehicle System Dynamics 63: 1–24.

12.

Liu

Wei

Zhu

, et al. (2024) Analysis of the influence of brake pipe pressure gradient on heavy haul combined train and optimisation of operation strategy. Vehicle System Dynamics 1–25. DOI: 10.1080/00423114.2024.2409773.

13.

(2022) Influencing factors and optimization measures for longitudinal impulse of 20 000-tonne combined heavy-haul trains. Electric Drive for Locomotives (1): 103–108.

14.

Yao

Meng

, et al. (2023) The design of electronically controlled pneumatic brake signal propagation mode for electronic control braking of a 30,000-ton heavy-haul train. Proceedings of the Institution of Mechanical Engineers, Part F: Journal of Rail and Rapid Transit 238(2): 268–279.

15.

Serajian

Mohammadi

Nasr

(2019) Influence of train length on in-train longitudinal forces during brake application. Vehicle System Dynamics 57: 192–206.

16.

Spiryagin

Cole

(2017) International benchmarking of longitudinal train dynamics simulators: benchmarking questions. Vehicle System Dynamics 55(4): 450–463.

17.

Sun

Ding

Zhou

(2017) Analysis and test of heavy haul train longitudinal impulse dynamics. Journal of Mechanical Engineering 53(8): 138–146.

18.

Wang

Chen

, et al. (2023) Review of dynamics research on heavy-haul train system. Chinese Journal of Applied Mechanics 40(5): 973–986.

19.

Wang

Zhou

, et al. (2025) Study on instrumental coupler for heavy haul train. Mechanics Based Design of Structures and Machines 53(3): 1927–1949.

20.

Wei

(2017) Analysis and application of train cycle braking parameters on the long steep descending grade. Railway Transport and Economy 39(10): 67–72.

21.

Spiryagin

Colin

(2016) Longitudinal train dynamics: an overview. Vehicle System Dynamics 54(12): 1688–1714.

22.

Spiryagin

Cole

(2017) Parallel computing scheme for three-dimensional long train system dynamics. Journal of Computational and Nonlinear Dynamics 12(4): 044502.

23.

Yang

(2007) Study on the Numerical Simulation and the Thermodynamic Model of the Tank Discharge Process. Shanghai: Shanghai Jiao Tong University.

24.

Zhang

Fan

, et al. (2024) Influence of cyclic pneumatic brake on the longitudinal dynamics of heavy-haul combined trains. IEEE Transactions on Intelligent Transportation Systems 25(3): 2545–2557.

25.

Zhang

Shi

Wang

, et al. (2025) Optimization study of pneumatic-electric combined braking strategy for 30,000-ton heavy-haul trains. Actuators 14(1): 40.

26.

Zhou

Cheng

, et al. (2024) Research on the air brake system of heavy haul trains based on neural network. Vehicle System Dynamics 62(8): 2035–2053.

27.

Zuo

Diao

Ding

, et al. (2025) Braking force distribution strategy for virtual rail trains based on I-curve. Journal of Vibration and Control. DOI: 10.1177/10775463251321198.

Study on the influence and optimization of blend braking strategy of train at gradient change point

Abstract

Keywords

Get full access to this article

References