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EHPV

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Principle of operation. Mathematical modeling. ... Development of a trainable nonlinear controller to compensate for inherent system non-linearities such as hysteresis. – PowerPoint PPT presentation

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Title: EHPV


1
EHPV TechnologySponsored by HUSCO Intl. the
FPMC Center
PATRICK OPDENBOSCH Graduate Research Assistant
NADER SADEGH Ph.D. Mechanical Engineering
Professor
WAYNE BOOK Ph.D. Mechanical Engineering Professor
Georgia Institute of Technology
George W. Woodruff School of Mechanical
Engineering
2
AGENDA
  • Valve overview.
  • Principle of operation.
  • Mathematical modeling.
  • Simulation results.
  • Non-linear controller.
  • Hardware-In-the-Loop (HIL)
  • Future work.

3
VALVE OVERVIEW
  • Electro-Hydraulic Poppet Valves (EHPV) are pilot
    operated valves used for flow control in
    hydraulic machinery.
  • The flow control is achieved by changing the
    valve restriction coefficient via a PWM input
    current acting on a pilot and a poppet type
    orifice with pressure compensation.

4
VALVE OVERVIEW
  • Bi-Directional Capability
  • Pressure compensation for consistent current at
    flow initiation.
  • Adequate Dynamic Response
  • Used in wheatstone configuration

5
VALVE OVERVIEW
COMPONENTS
6
PRINCIPLE OF OPERATION
  • Forward Flow
  • Pressure at port A
  • is higher than that
  • at port B.

Port A
Port B
7
PRINCIPLE OF OPERATION
  • Forward Flow
  • Pilot pin and armature
  • displaced due to hydraulic
  • imbalance

Pressure compensating spring acts to balance
pilot pin
Port A
Port B
8
PRINCIPLE OF OPERATION
  • Forward Flow
  • Solenoid is activated and hydraulic fluid is
    drained to low pressure side

Port A
Port B
9
PRINCIPLE OF OPERATION
  • Forward Flow
  • Main poppet is displaced to a new equilibrium
  • position allowing a
  • direct connection
  • between ports A and B

Port A
Port B
10
MATHEMATICAL MODELING
  • The mathematical modeling is based on the
    interaction of three subsystems

Electromagnetic
Mechanical
Hydraulic
11
MECHANICAL SYSTEM
Modulating spring
Pilot pin mass
Armature mass
Bias spring
Piston mass
Pressure compensating spring
Main poppet mass
12
MECHANICAL SYSTEM
Pilot Armature Piston Combined
  • MODE 1 (closed)
  • Pilot-Armature-Piston Dynamics
  • Main Poppet Dynamics

Main Poppet
13
MECHANICAL SYSTEM
  • MODE 2 (open)

Pilot Armature
Piston
Main Poppet
14
MECHANICAL SYSTEM
  • MODE 2 (open)
  • Pilot-Armature Dynamics

Pilot Armature
Main Poppet
15
MECHANICAL SYSTEM
  • MODE 2 (open)
  • Piston Dynamics

Piston
Main Poppet
16
MECHANICAL SYSTEM
  • MODE 2 (open)
  • Main Poppet Dynamics

Pilot Armature
Piston
Main Poppet
17
MECHANICAL SYSTEM
  • State Constraints

- Main Poppet
Pilot Armature
- Pilot Armature
Piston
Main Poppet
- Piston
18
HYDRAULIC SYSTEM
Pilot Head Chamber
Bi-Directional Capability
Control Pressure Chamber
C2
C1
C
A
B
FORWARD FLOW DIAGRAM
C1
C2
  • Forward Flow

A
C
  • Reverse Flow

B
19
HYDRAULIC SYSTEM
Pilot Head Chamber
Control Pressure Chamber
C
A
B
C1
C2
A
C
B
20
HYDRAULIC SYSTEM
A
A
View A-A
21
HYDRAULIC SYSTEM
Pilot Head Chamber
Control Pressure Chamber
C
A
B
C1
C2
Neglecting compressibility effects
A
C
B
22
ELECTRO-MAGNETIC SYSTEM
Rsol
Vsol
isol
gmax
23
ELECTRO-MAGNETIC SYSTEM
Rsol
Vsol
isol
gmax
24
ELECTRO-MAGNETIC SYSTEM
Rsol
Vsol
isol
gmax
Hysteresis
25
SIMULATION RESULTS
  • EHPV Step Response (0-90 capacity)

26
NON-LINEAR CONTROLLER
  • Motor Speed Control

CONTROLLER
EHPV
Pump
M
M
Load Motor
Tank
27
NON-LINEAR CONTROLLER
  • Scheme

Closed-Loop Control
Open-loop Control
  • Look-up table
  • Generate Kv for given pressure differential
  • Trainable/tailored
  • PI type
  • Generates duty cycle for PWM driver
  • Needs control variable measurement feedback

28
NON-LINEAR CONTROLLER
  • Closed-loop Control

EHPV
PI Controller
Load Motor
Reference
PWM Driver
Sampled Error
100
0
(Duty Cycle)
PI Controller
29
NON-LINEAR CONTROLLER
  • Open-loop Control

EHPV
Controller
Load Motor
Converter/ PWM Driver
Look-UpTable
Controller
30
HARDWARE-IN-THE-LOOP
  • The Hardware-In-the-Loop (HIL) simulation
    facility located at the Intelligent Machine
    Dynamics Laboratory (IMDL) will be exploited for
    model validation, controller training, and
    control implementation.

Hydraulic Circuit for Single Valve Identification
31
HARDWARE-IN-THE-LOOP
Hardware-In-the-Loop Facility at IMDL
Hydraulic Circuit for 4-Way EHPV Control Training
32
FUTURE WORK
  • 1. Model validation for a single valve.
  • 2. Model validation for 4-way directional valve
    arrangement.
  • 3. Tune-up and test non-linear controller.
  • 4. Development of Robust algorithms for tailored
    electronic valve flow coefficient correction.
  • 5. Simulation and testing of four different flow
    metering modes, and study their effects.
  • 6. Development of a trainable nonlinear
    controller to compensate for inherent system
    non-linearities such as hysteresis.
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