Hydromechanical compensators are often integrated with piston-type pumps to produce various control behavior, for example, pressure, load-sensing, power, or torque control. Various hydromechanical mechanisms (e.g., spring forces and load pressure) are found in the industry to ensure the desired effect of the system outputs: swash angle, discharge pressure, and input torque following the reference inputs. In a companion paper (Part I of this paper), a generic linearized state-space model is derived to investigate the pump dynamics and determine the design criteria and parameters. In the study, the state-space equations are used to propose and define the generic compensating control pump to conduct the similar strategies as hydromechanical pumps do. The different control purposes (pressure/flow/power compensating) are accomplished by only manipulating the generic regulate inputs given by an electrical proportional control valve. In the open-circuit pump, the generic controllers are proposed to generate these inputs by using one unique mechanical and electronic architecture to establish various purposes of flow, pressure, torque desired control, and even more control objectives. The controller is developed in accordance with the state-space representation and by following the models of the hydromechanical compensators that can facilitate the correlation verification. The proposed controllers are able to offer more intelligent and cost-saving control strategies for open-circuit piston pumps. To achieve the similar performance as hydromechanical compensators do and implement the comparative study, control gains and settings in the controller can be determined from ones that hydromechanical compensators have. The difference is that electronic signals (swash plate position, pressure, etc.) work as feedbacks together with other control gains to regulate the input signals. For the different control purposes, control gains are able to be set conveniently for the various control operating conditions with combining the certain feedbacks on the same hardware platform that will be value efficient and capable of control intelligence. In the paper, results of predictions made by the model are presented and compared with some experimental data of hydromechanical designs. Further work on the advanced model-based control and estimation is anticipated to be addressed.

References

1.
Zeiger
,
G.
, and
Akers
,
A.
,
1985
, “
Torque on the Swash Plate of an Axial Piston Pump
,”
ASME J. Dyn. Syst., Meas., Control
,
107
(
3
), pp.
220
226
.
2.
Manring
,
N.
,
1999
, “
The Control and Containment Forces on the Swash Plate of an Axial-Piston Pump
,”
ASME J. Dyn. Syst., Meas., Control
,
121
(
4
), pp.
599
605
.
3.
Manring
,
N.
,
2001
, “
The Control Torque on the Swash Plate of an Axial-Piston Pump Utilizing Piston-Bore Springs
,”
ASME J. Dyn. Syst., Meas., Control
,
123
(3), pp.
471
478
.
4.
Schoenau
,
G. J.
,
Burton
,
R. T.
, and
Kavanagh
,
G. P.
,
1990
, “
Dynamic Analysis of a Variable Displacement Pump
,”
ASME J. Dyn. Syst., Meas., Control
,
112
(
1
), pp.
122
132
.
5.
Manring
,
N. D.
, and
Johnson
,
R. E.
,
1996
, “
Modeling and Designing a Variable-Displacement Open-Loop Pump
,”
ASME J. Dyn. Syst., Meas., Control
,
118
(
2
), pp.
267
271
.
6.
Zhang
,
X.
,
Cho
,
J.
,
Nair
,
S. S.
, and
Manring
,
N. D.
,
2001
, “
New Swash Plate Damping Model for Hydraulic Axial-Piston Pump
,”
ASME J. Dyn. Syst., Meas., Control
,
123
(
3
), pp.
463
470
.
7.
Hwang
,
C.
,
1999
, “
Neural-Network-Based Variable Structure Control of Electrohydraulic Servosystems Subject to Huge Uncertainties Without Persistent Excitation
,”
IEEE/ASME Trans. Mechatronics
,
4
(
1
), pp.
50
59
.
8.
Haggag
,
S.
,
Alstrom
,
D.
,
Cetinkunt
,
S.
, and
Egelja
,
A.
,
2005
, “
Modeling, Control, and Validation of an Electro-Hydraulic Steer-by-Wire System for Articulated Vehicle Applications
,”
IEEE/ASME Trans. Mechatronics
,
10
(
6
), pp.
688
692
.
9.
Kaddissi
,
C.
,
Kenne
,
J.-P.
, and
Saad
,
M.
,
2007
, “
Identification and Real-Time Control of an Electrohydraulic Servo System Based on Nonlinear Backstepping
,”
IEEE/ASME Trans. Mechatronics
,
12
(
1
), pp.
12
22
.
10.
Kaddissi
,
C.
,
Kenne
,
J.-P.
, and
Saad
,
M.
,
2010
, “
Indirect Adaptive Control of an Electrohydraulic Servo System Based on Nonlinear Backstepping
,”
IEEE/ASME Trans. Mechatronics
,
16
(
6
), pp.
1
8
.
11.
Du
,
H.
,
2002
, “
Pressure Control With Power Limitation for Hydraulic Variable Displacement Piston Pumps
,”
American Control Conference
, Anchorage, AK, May 8–10, Vol.
2
, pp.
940
945
.
12.
Wang
,
S.
, “
Generic Modeling and Control of an Open-Circuit Piston Pump—Part I: Theoretical Model and Analysis
,”
ASME J. Dyn. Syst., Meas., Control
(to be published).
13.
Manring
,
N. D.
,
2005
,
Hydraulic Control Systems
,
Wiley
,
Hoboken, NJ
.
14.
SAE J745
,
1996
,
Surface Vehicle Recommended Practice—Hydraulic Power Pump Test Procedure
,
Society of Automotive Engineers
,
Warrendale, PA
.
You do not currently have access to this content.