Design and characteristic research of a novel electromechanical-hydraulic hybrid actuator with two transmission mechanisms
Shufei QIAO, Long QUAN(), Yunxiao HAO, Lei GE, Lianpeng XIA
Key Laboratory of Advanced Transducers and Intelligent Control System of Ministry of Education, Taiyuan University of Technology, Taiyuan 030024, China
Servo-hydraulic actuators (SHAs) are widely used in mechanical equipment to drive heavy-duty mechanisms. However, their energy efficiency is low, and their motion characteristics are inevitably affected by uncertain nonlinearities. Electromechanical actuators (EMAs) possess superior energy efficiency and motion characteristics. However, they cannot easily drive heavy-duty mechanisms because of weak bearing capacity. This study proposes and designs a novel electromechanical-hydraulic hybrid actuator (EMHA) that integrates the advantages of EMA and SHA. EMHA mainly features two transmission mechanisms. The piston of the hydraulic transmission mechanism and the ball screw pair of the electromechanical transmission mechanism are mechanically fixed together through screw bolts, realizing the integration of two types of transmission mechanisms. The control scheme of the electromechanical transmission mechanism is used for motion control, and the hydraulic transmission mechanism is used for power assistance. Then, the mathematical model, structure, and parameter design of the new EMHA are studied. Finally, the EMHA prototype and test platform are manufactured. The test results prove that the EMHA has good working characteristics and high energy efficiency. Compared with the valve-controlled hydraulic cylinder system, EMHA exhibits a velocity tracking error and energy consumption reduced by 49.7% and 54%, respectively, under the same working conditions.
. [J]. Frontiers of Mechanical Engineering, 2023, 18(2): 19.
Shufei QIAO, Long QUAN, Yunxiao HAO, Lei GE, Lianpeng XIA. Design and characteristic research of a novel electromechanical-hydraulic hybrid actuator with two transmission mechanisms. Front. Mech. Eng., 2023, 18(2): 19.
Compared with the valve-controlled hydraulic cylinder system
Hydraulic power ratio
> 80%
Movement stage
Tab.4
Abbreviations
EHA
Electro-hydrostatic actuator
EMA
Electromechanical actuator
EMHA
Electromechanical-hydraulic hybrid actuator
SHA
Servo-hydraulic actuator
Variables
A1, A2
Effective action areas of the EMHA rodless and rod chamber pressure, respectively
B
Rotational viscous friction coefficient
c
System viscous damping coefficient
d
Outer diameter of the piston rod
dc
Outer diameter of the cylinder barrel
ds
Diameter of the lead screw
d1, d2
Diameters of the piston and piston rod, respectively
De
Servo motor width
Dz1
Wheelbase between the servo motor and the lead screw
Dz2
Wheelbase between the driving gear and the driven gear
Fe
Electromechanical transmission mechanism force
FE
Output force of EMA
FER
Radial force of the driving rod of EMA
Ff
Interference force including friction
Fh
Hydraulic transmission mechanism force
FH
Output force of SHA
FHR
Radial force of the driving rod of SHA
FL
Load force
Fsum
Total output force
id
Stator current of the d axis
iq
Stator current of the q axis
I
Current of the electrical unit
J1, J2
Moments of inertia of the servo motor rotor and reducer, respectively
Je
Moment of inertia driven by the electrical unit
JL
Equivalent moment of inertia of the load
Js
Moment of inertia of the lead screw
k
Reducer reduction ratio
l
Lead of the screw transmission pair
LE
Arm distance of the EMA output force
LH
Arm distance of the SHA output force
Ls
Equivalent inductance
m
Gear module
mh
Hydraulic oil mass
ml
Load mass
ms
Lead screw mass
n
Rotation speed of the servo motor
ns
Rotation speed of the lead screw
N
Number of the pole pairs
p1, p2
Pressures of the EMHA rodless and rod chamber, respectively
Ph
Driving power of the hydraulic cylinder
R
Stator resistance
T
Torque amplified through the reducer
Tadd
Additional torque of the distributed linear drive system
TL
Equivalent load torque of the servo motor
ud
Stator voltage of the d axis
uq
Stator voltage of the q axis
U
Voltage of electrical unit
v
Velocity of EMHA
vs
Linear speed of the lead screw rotation
x
Displacement of EMHA
z1, z2, z3
Numbers of the driving teeth, transition teeth, and driven teeth, respectively
α
Rotation angle of the servo motor
ψ
Flux linkage amplitude of the rotor permanent magnet
η1, η2
Efficiency of the mechanical and hydraulic transmission mechanism, respectively
θ
A certain angle
θE
Angle between the load force of the EMA driving rod and axis
θH
Angle between the load force of the SHA driving rod and axis
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