Hydraulic servo motors are widely used in aircraft utility systems due to their highefficiency bidirectional variable displacement drive characteristics.However,the displacement changes process leads to severe frictio...Hydraulic servo motors are widely used in aircraft utility systems due to their highefficiency bidirectional variable displacement drive characteristics.However,the displacement changes process leads to severe friction losses between the swashplate and the bearing,and effective solutions are currently lacking.To address this issue,a Hydrodynamic Swashplate-Bearing Pair(HSBP)structure is proposed for hydraulic servo motors,which avoids the direct contact problem of traditional structures.A numerical calculation model for the HSBP is established,the axial displacement phenomenon generated during the reciprocating motion of the swash plate is considered,and a local mobility method is introduced to solve the frictional characteristic pa-rameters of the new friction pair.The analysis and calculation results obtained the influence law of different working condition parameters and structural parameters on the friction characteristics.A quasi-actual friction test bench is developed to simulate the actual motion characteristics of the swashplate,simplifying the testing method for the friction pair.The experimental results show an error of less than10%compared to the calculated results.Additionally,the experimental results demonstrate that the proposed hydrodynamic swashplate bearing structure can effectively reduce the friction force during the displacement adjustment process of hydraulic servo motors by more than 90%compared to traditional swashplate bearing structures.展开更多
With the continuous development of science and technology and the growing severity of energy issues,load-sensitive drive systems have attracted significant attention in the electro–hydraulic servo field due to their ...With the continuous development of science and technology and the growing severity of energy issues,load-sensitive drive systems have attracted significant attention in the electro–hydraulic servo field due to their high energy efficiency.Currently,most research primarily focuses on introducing load-sensitive valves to achieve load-following through hydraulic-mechanical feedback.This approach has partially achieved the energy-saving goal,but issues such as reduced dynamic response speed and limited load-sensitive range due to mechanical structures remain.This paper proposes an active load-sensitive variable displacement drive system that no longer relies on mechanical structures for load-sensitive adjustment.And multiple energy efficiency mapping relationships are designed to complete the system's load-sensitive adjustment,thereby reducing throttling losses.Additionally,a dual-loop anti-disturbance control method based on energy efficiency mapping is proposed.An appropriate Lyapunov function is selected to prove that the control system ultimately tends to be bounded and stable,successfully solving the multiplicative nonlinear coupling control problem caused by the variable mechanism,and improving the system's position control accuracy.Experimental results show that under this control method,the active loadsensitive drive system can reduce flow by up to 60 % compared to the traditional fixed displacement hydraulic motor drive system.Compared to conventional PID control,the proposed method can improve control accuracy by up to 50 %,effectively reducing energy consumption while improving the position control accuracy of the active load-sensitive variable motor drive system.展开更多
基金supported by the National Natural Science Foundation of China(No.52205045)the Natural Science Foundation of Hebei Province,China(No.E2024203244)the Aeronautical Science Foundation of China(No.2022Z029051001)。
文摘Hydraulic servo motors are widely used in aircraft utility systems due to their highefficiency bidirectional variable displacement drive characteristics.However,the displacement changes process leads to severe friction losses between the swashplate and the bearing,and effective solutions are currently lacking.To address this issue,a Hydrodynamic Swashplate-Bearing Pair(HSBP)structure is proposed for hydraulic servo motors,which avoids the direct contact problem of traditional structures.A numerical calculation model for the HSBP is established,the axial displacement phenomenon generated during the reciprocating motion of the swash plate is considered,and a local mobility method is introduced to solve the frictional characteristic pa-rameters of the new friction pair.The analysis and calculation results obtained the influence law of different working condition parameters and structural parameters on the friction characteristics.A quasi-actual friction test bench is developed to simulate the actual motion characteristics of the swashplate,simplifying the testing method for the friction pair.The experimental results show an error of less than10%compared to the calculated results.Additionally,the experimental results demonstrate that the proposed hydrodynamic swashplate bearing structure can effectively reduce the friction force during the displacement adjustment process of hydraulic servo motors by more than 90%compared to traditional swashplate bearing structures.
基金supported by the National Natural Science Foundation of China(No.52205045)the Natural Science Foundation of Hebei Province,China(No.E2024203244)the Aeronautical Science Foundation of China(No.2022Z029051001)。
文摘With the continuous development of science and technology and the growing severity of energy issues,load-sensitive drive systems have attracted significant attention in the electro–hydraulic servo field due to their high energy efficiency.Currently,most research primarily focuses on introducing load-sensitive valves to achieve load-following through hydraulic-mechanical feedback.This approach has partially achieved the energy-saving goal,but issues such as reduced dynamic response speed and limited load-sensitive range due to mechanical structures remain.This paper proposes an active load-sensitive variable displacement drive system that no longer relies on mechanical structures for load-sensitive adjustment.And multiple energy efficiency mapping relationships are designed to complete the system's load-sensitive adjustment,thereby reducing throttling losses.Additionally,a dual-loop anti-disturbance control method based on energy efficiency mapping is proposed.An appropriate Lyapunov function is selected to prove that the control system ultimately tends to be bounded and stable,successfully solving the multiplicative nonlinear coupling control problem caused by the variable mechanism,and improving the system's position control accuracy.Experimental results show that under this control method,the active loadsensitive drive system can reduce flow by up to 60 % compared to the traditional fixed displacement hydraulic motor drive system.Compared to conventional PID control,the proposed method can improve control accuracy by up to 50 %,effectively reducing energy consumption while improving the position control accuracy of the active load-sensitive variable motor drive system.
