The energy saving of hydraulic excavators is always an essential research. An energy recovery system caneffectively recover the boom potential energy and rotational kinetic energy. Based on the standard working cycle of hydraulicexcavators, a dynamic programming (DP) control strategy for hybrid hydraulic excavators was proposed to recover the boompotential energy and rotational kinetic energy. The hybrid hydraulic excavator simulation model was built by Simulinksoftware. The simulation results indicated that the fuel consumption of hybrid hydraulic excavators using the DP controlstrategy was about 21.3% lower than that of the conventional hydraulic excavator. In order to experimentally verify thesimulation results, an experimental platform for hybrid hydraulic excavators was built. The experimental results indicated thatthe fuel consumption of hybrid hydraulic excavators using the DP control strategy was about 18.9% lower than that of theconventional hydraulic excavator. This paper shows that the DP control strategy applied to hybrid hydraulic excavators canrecycle the boom potential energy and rotational kinetic energy, and reduce the fuel consumption of hybrid hydraulicexcavators.
Keywords: hybrid excavator, energy recovery, control strategy, simulation analysis, test platform
DOI: 10.25165/j.ijabe.20241702.7774

Citation: Liu C S, He Q H, Tang Q J, Ren K, Gong J, Zhang D Q. Novel control strategy for the energy recovery system of a hydraulic excavator. Int J Agric & Biol Eng, 2024; 17(2): 94–101.

hybrid excavator, energy recovery, control strategy, simulation analysis, test platform

Zhang S Y, Peng K M, Wei W L. The matrix method of energy analysis and energy-saving design on the electromechanical system. Energy, 2021; 224(1): 1–11.

Meng Z, Tang G, Zhou Q. A review of hybrid electric vehicle energy management strategy based on road condition information. IOP Conference Series:Earth and Environmental Science, 2021; 831: 012031.

He X Y, Jiang Y. Review of hybrid electric systems for construction machinery. Automation in Construction, 2018; 92: 286–296.

Chen Q H, Lin T L, Ren H L. Novel potential energy regeneration systems for hybrid hydraulic excavators. Mathematics and Computers in Simulation, 2019; 163: 130–145.

Ge L, Dong Z X, Quan L, Li Y W. Potential energy regeneration method and its engineering applications in large-scale excavators. Energy Conversion and Management, 2019; 195: 1309–1318.

Do T C, Dang T D, Dinh T Q. Developments in energy regeneration technologies for hydraulic excavators: A review. Renewable & Sustainable Energy Reviews, 2021; 145: 20.

Chen J S, Huo D Y, Liu C Y, Zhang H, Wang Y Q. Design and modeling of hardware-in-loop test bench for hydraulic excavator based on dynamic load emulation. Automation in Construction, 2022; 137: 10.

Chen Q H, Lin T L, Ren H L. Parameters optimization and control strategy of power train systems in hybrid hydraulic excavators. Mechatronics, 2018; 56: 16–25.

Hao Y X, Quan L, Cheng H, Xia L P, Ge L, Zhao B. Potential energy directly conversion and utilization methods used for heavy duty lifting machinery. Energy, 2018; 155: 242–251.

Yin Y L, Zhang L F, Zhan S, Ma Y J, Ma S P. A novel state energy spatialization regenerative braking control strategy based on Q-learning algorithm for a super-mild hybrid electric vehicle. International Journal of Green Energy, 2021; 18: 1265–1278.

Han T L, Zeng B, Tong Y J. Theoretical study on energy recovery rate of regenerative braking for hybrid mining trucks with different parameters. Journal of Energy Storage, 2021; 42: 5.

Sun Y T, Wang Y L, Zhu R F, Geng R G, Zhang J Z, Fan D H, et al. Study on the control strategy of regenerative braking for the hybrid electric vehicle under typical braking condition. IOP Conference Series:Materials Science and Engineering, 2018; 452: 032092.

Do T C, Nguyen D G, Dang T D. A boom energy regeneration system of hybrid hydraulic excavator using energy conversion components. Actuators, 2021; 10: 16.

Ranjan P, Wrat G, Bhola M. A novel approach for the energy recovery and position control of a hybrid hydraulic excavator. ISA Transactions, 2020; 99: 387–402.

Yu Y-X, Ahn K K. Improvement of energy regeneration for hydraulic excavator swing system. International Journal of Precision Engineering and Manufacturing-Green Technology, 2020; 7: 53–67.

Hu P, Zhu J X, Gong J, Zhang D Q, Liu C S, Zhao Y M, et al. Development of a comprehensive driving cycle for construction machinery used for energy recovery system evaluation: A case study of medium hydraulic excavators. Mathematical Problems in Engineering, 2021; 2021: 13.

Yu Y-X, Ahn K K. Optimization of energy regeneration of hybrid hydraulic excavator boom system. Energy Conversion and Management, 2019; 183: 26–34.

Yu Y X, Do T C, Park Y. Energy saving of hybrid hydraulic excavator with innovative powertrain. Energy Conversion and Management, 2021; 244: 10.

Chen Q, Lin T, Ren H. Direct torque control of a permanent magnet synchronous machine for hybrid hydraulic excavator. IET Electric Power Applications, 2019; 13: 222–228.

Zhang W, Wang J X, Du S F, Ma H F, Zhao W J, Li H J. Energy management strategies for hybrid construction machinery: Evolution, classification, comparison and future trends. Energies, 2019; 12(10): 1–26.

Bayindir K C, Gozukucuk M A, Teke A. A comprehensive overview of hybrid electric vehicle: Powertrain configurations, powertrain control techniques and electronic control units. Energy Conversion and Management, 2011; 52: 1305–1313.

Rotenberg D, Vahidi A, Kolmanovsky I. Ultracapacitor assisted powertrains: modeling, control, sizing, and the impact on fuel economy. IEEE Trans Control Syst Technol, 2011; 19: 576–589.

Chen S-Y, Wu C-H, Hung Y-H. Optimal strategies of energy management integrated with transmission control for a hybrid electric vehicle using dynamic particle swarm optimization. Energy, 2018; 160: 154–170.

Zhou H, Zhao P-Y, Chen Y-L. Fuzzy logic control for a hydraulic hybrid excavator based on torque prediction and genetic algorithm optimization. Proceedings of the Institution of Mechanical Engineers Part D-Journal of Automobile Engineering, 2018; 232: 983–994.

Zhang W B, Li J Q, Xu L F, Ouyang M G. Optimization for a fuel cell/battery/capacity tram with equivalent consumption minimization strategy. Energy Conversion and Management, 2017; 134: 59–69.

Xu B, Rathod D, Zhang D R, Filipi Z. Parametric study on reinforcement learning optimized energy management strategy for a hybrid electric vehicle. Applied Energy, 2020; 259: 21.

Sprengel M M, Ivantysynova M. Investigation and energetic analysis of a novel hydraulic hybrid architecture for on-road vehicles. 13th Scandinavian International Conference on Fluid Power; June 3-5; 2013; Linköping; Sweden: Linköping University Electronic Press; 2013; pp.87–98.

Chen Q H, Lin T L, Ren H L, Fu S J. Research on the control strategy of power train systems for hybrid hydraulic excavators. Advances in Mechanical Engineering, 2018; 10(7): 1–10.

Truong H V A, Dao H V, Do T C, Cong M H, Xuan D T, Dang T D, et al. Mapping fuzzy energy management strategy for pem fuel cell-battery-supercapacitor hybrid excavator. Energies, 2020; 13: 27.

Dao H V, To X D, Truong H V A. Optimization-based fuzzy energy management strategy for PEM fuel cell/battery/supercapacitor hybrid construction excavator. International Journal of Precision Engineering and Manufacturing-Green Technology, 2021; 8: 1267–1285.

Kim H-G, Yoo S-J, Cho S-W, Yi K-S. Hybrid control algorithm for fuel consumption of a compound hybrid excavator. Automation in Construction, 2016; 68: 1–10.

Lee H-Y, Song C-H, Kim N, Cha S. Comparative analysis of energy management strategies for HEV: dynamic programming and reinforcement learning. IEEE Access, 2020; 8: 67112–67123.

Peng J K, He H W, Xiong R. Rule based energy management strategy for a series-parallel plug-in hybrid electric bus optimized by dynamic programming. Applied Energy, 2017; 185: 1633–1643.

Yang Y L, Hu X S, Pei H X, Peng Z Y. Comparison of power-split and parallel hybrid powertrain architectures with a single electric machine: Dynamic programming approach. Applied Energy, 2016; 168(C): 683–690.

State Administration for Market Regulation, Standardization Administration of China. Earth-moving machinery—Fuel consumption for hydraulic excavator—Test methods: GB/T 36695-2018. Beijing: China standard Press, 2018; p. 20. (in Chinese)