increasing energy efficiency by model based design · 11 model based design taking into account...
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INCREASING ENERGY EFFICIENCY BY MODEL BASED DESIGN
GREGORY PINTETHE MATHWORKS CONFERENCE 2015EINDHOVEN
23/06/2015
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FLANDERS MAKE
Strategic Research Center for the manufacturing industry
Integrating the power of industry, industrial research centers (FMTC, Flanders’ DRIVE) & university research labs in one common research agenda
Open innovation environment enabling structuralcollaboration in research between industry - Flanders Make -academia
Accelerate technological innovation in the Flemishmanufacturing industry
Cross-border and international collaboration
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MISSION FLANDERS MAKE
“To strengthen the long-term international competitiveness of the
Flemish manufacturing industry
by carrying out
excellent, industry-driven, pre-competitive research
in the domains of mechatronics, product development methods
and advanced manufacturing technologies”
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FLANDERS MAKE RESEARCH PROGRAMS
Clean energy efficient motion systems
Smart monitoring systems
High-performance Autonomous Mechatronic Systems
Intelligent product design methods
Design and Manufacturing of Smart and Lightweight Structures
Additive Manufacturing
Manufacturing for high precision products
Agile & Human-centered production and robotic systems
Model based design for energy efficiency!
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Overview
Introduction
Example 1: energy storage in a hydrostatic drivetrain
Example 2: energy efficiency increase of a badminton robot
Summary and conclusions
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NEED FOR INCREASED ENERGY EFFICIENCY
INTRODUCTION
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Background: scarcity of energy
Societal awareness
Consider energetic impact of the things you are doing
Be ‘green’
Increasingly stringent legislation
Economic angle
Increasing prices for energy
Contribution of cost of consumed energy during use phase of machine in Total Cost of Ownership increases
As a results
Need to reduce energetic footprint machines
Energy efficiency (during use phase) becomes a differentiating performance characteristic
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Reduce energy consumption during the use phase (I)
General approach
1. Avoid useless energy consumption
– E.g. Reduce stand-by losses
2. Minimize inevitable losses in functional components
– E.g. Use energy efficient components, e.g. energy-efficient
motors
3. If the process generates energy, recuperate it or reuse it
– Braking energy
– Waste heat
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Reduce energy consumption during the use phase (II)
Applied to drivelines of production machines and vehicle
Component level
– Use energy efficient components
– However: might cause performance changes, e.g. electrical motor
for dynamic applications
System level
– Allows taking into account interaction between components in
machine
– Most opportunities, but less straightforward
Take energy consumption into account during the design of new
machines
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Motivation, vision, objective and approach
Vision
Future mechatronic systems will be developed following a model-
based design approach
Motivation
Model-based design is essential to– Reduce development effort/cost
– Decrease the time-to-market
– Explore the space of possible designs more rigorously
– Deal with increasing number of system requirements
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Model based design taking into account energy efficiency
Model based design
Opportunity to quickly evaluate the impact of design changes
– Describe behavior components mathematically
– Combine components
– Simulate and analyze machine behavior
Difficulty with energy
– Multi-disciplinary (mechanical, electrical, hydraulic, etc.)
– Changes form during a machining process
– 1D Simulation softwares exist that allow modeling of energetic
behaviour
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CASE STUDY 1:ENERGY STORAGE IN A HYDROSTATIC DRIVETRAIN
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Hydrostatic drivetrain
Heavy load vehicles
Hydrostatic drivetrain
– Combustion engine to pump to hydraulic motors to 1 or more
loads
– Variable stroke volumes
continuously variable transmission ratio
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Hydrostatic drivetrain
Experimental setup at FMTC
Simulate a loaded hydrostatic drivetrain
– Speed controlled electric motor instead of diesel engine
– Torque controlled electric motors and flywheels to emulate load
Energy storage?
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Concept generation
Concept generation
Model-based concept analysis
Concept selection
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Energetic model
Start from model of original set-up
Identify loss parameters based on experiments
Expand model with models of energy storage elements
Concept generation
Model-based concept analysis
Concept selection
Pump
Driving
motor
Hydraulic
circuit
Hydro
motor 1
Hydro
motor 2
Load1
Load2
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Component optimization
Cost function
Total cost of ownership
Optimal control
Electrical hybrid
Capacitor bank dimensioning
– Number of capacitors per serial branch
– Number of parallel branches
Hydraulic hybrid
Accumulator volume
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Concept selection
Energy lossesTotal cost
Concept generation
Model-based concept analysis
Concept selection
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Physical interpretation
Electrical hybrid
Hydraulic hybrid
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CASE STUDY 2:ENERGY EFFICIENCY INCREASE OF A BADMINTON ROBOT
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Badminton robot
Demonstration platform
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First attempt to reduce energy consumption
Engineering reasoning of main losses
Robot is mainly accelerating and decelerating masses
Deceleration energy is ‘burned’ in braking resistor
Reduce energy consumption?
Recuperate braking energy and reuse this energy
Capacitors added to system
Very little reduction in energy consumption (under 5%)!
Why is this so?
More systematic analysis needed!
v
t
accmax decmax
vmax
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Goal of the analysis
Energy consuming elements in model
E.g. Brake resistance, coil resistance, friction,…
Parameter tuning
– From catalogues (e.g. motor parameters)
– Experimentally (e.g. friction parameters)
PlantPosition
Controller
Trajectory
generatorTarget
position
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Energy analysis
+ Energy flow analysis results
Main loss can be attributed to copper losses and friction losses
+ Solution?
Reduce friction losses
Other guides? => reduce friction
~I2; I~F; F~acceleration => reduce acceleration!
Region Region Region Region
Energy flow without additionnal capacitance - Simulation
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Improvement: Energy efficient controller
Go from Time Optimal to Just-In-Time controller
Current implementation
– Time optimal
Just-in-time controller
– Same structure
– Bounds on trajectory parameters: Vmax and Amax
– Parameters found using Multi-Objective optimization using the
model of the robot
Significant reduction in energy consumption!
… without loss of effectiveness!
– more than 50 % of energy reduction
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Industrial application
Similar design analysis and controller development has been applied to
the design of the drivetrain of a crane
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CONCLUSIONS
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Conclusion
Motivation: Energy reduction for environmental and economic reasons
Approach
Take energy consumption into account on system level
Following mechatronic model based approach allows to optimize
(energy efficiency of) the design