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1 | Corporate Presentation, September 20, 2016
Hardware-in-the-loop (HIL) Test of Demand as Frequency controlled Reserve (DFR)
QIUWEI WU/Associate ProfessorCenter for Electric Power and Energy (CEE)
Technical University of Denmark (DTU) 15th September 2016
Outline• PowerLabDK
• Wind power in Denmark
• DFR control logics
• Heat pump model
• HIL test
• Conclusions
PowerLab Combines Experimental Facilities in a Unique Platform
Stakeholders:
Supported by:
Investment:18 million Euro
TECHNOLOGY DEVELOPMENT TESTING TRAINING DEMONSTRATION
Lyngby & Ballerup Campus Risø Campus
Flexible multi-purpose laboratories
The Island Bornholm
Large-scale test system
Full-scale real-lifeenergy system
40,000 people33% wind power50% renewable energyIslanding capability
Bornholm - Full-scale Living Laboratory with 40,000 Inhabitants and 50% Renewable Energy Penetration
Bornholm
Resources:- Wind power- Biomass - Biogas- District heating- Combined heat and power- Solar power- eMobility- Active demand
Features:- Nord Pool market- Islanding capability
TECHNOLOGY DEVELOPMENT TESTING TRAINING DEMONSTRATION
Intelligent Control Lab - Test-bed for Integrated Experiments
Grid in Lab
w. 22LabCells
Full-scalecontrol room
Real-time digital simulator
Power amplifier 150 kW (1.2 MW)
SCADAsystem
Models
Power hardwaretest in lab
Onlinedata
LabGrid with 21 LabCells
Onlinecontrol/
data
Online control/data
Power
Power
I/O
Blade Center(power market/controllers)
Online control/data
Real worldControl hardware
test in labI/O
Outline• Intelligent control lab of PowerLabDK
• Wind power in Denmark
• DFR control logics
• Heat pump model
• HIL test
• Conclusions
Year 2014Danish wind power generation: 39.1% of the electricity consumption
January 2014Danish wind power generation: 63.3% of the electricity consumption
December 21th 2013Danish wind power generation: 102% of the electricity consumption
Single hour July 9th 2015Danish wind power generation: 140% of the electricity consumption
March 11th 2014only 9 MW wind power generated out of installed 4,900 MW
but 480 MW out of 580 MW solar units supplied the grid
Wind Power in Denmark
0
1000
2000
3000
4000
5000
6000
7000
MW
h/h
201225% wind power
DemandWind Power
202050% wind power
DemandWind Power
Wind Power in Denmark
Outline• Intelligent control lab of PowerLabDK
• Wind power in Denmark
• DFR control logics
• Heat pump model
• HIL test
• Conclusions
DFR Control Logic
The DFR control logic type I disconnects and reconnects electric appliances to the grid when the system frequency falls below and recovers above , respectively
offf
onf
DFR Control LogicThe DFR control logic type II is customized for switching thethermostatically controlled loads by adjusting the nominaltemperature set points and .normal
lowT
0( )normalhigh highT T kf f f= + −
0( )normallow lowT T kf f f= + −
normalhighT
Outline• Intelligent control lab of PowerLabDK
• Wind power in Denmark
• DFR control logics
• Heat pump model
• HIL test
• Conclusions
Heat Pump Model• The dynamics of a direct air heating system can be sufficiently
described by three thermal masses.• The ambient air of the building interior has smaller storage
volume, and defines a faster dynamics of the system.• the larger storage volume of the building envelope, or structure,
describes a slower dynamics of the system
( ) ( )1 1i e i a i H w s
i ie ia
IT T T T T Q AC R R
= − + − + + Φ
( ) ( )1 1e a e e e s
e ea iei
IT T T T T AC R R
= − + − + Φ
Outline• Intelligent control lab of PowerLabDK
• Wind power in Denmark
• DFR control logics
• Heat pump model
• HIL test
• Conclusions
HIL Test
HIL Test
00:00:00 00:10:00 00:20:00 00:30:0019.5
20
20.5
21
o C
On/off control
Tinside
Tstructure
00:00:00 00:10:00 00:20:00 00:30:000
5
10
kW
Pelectricity
Pheat
00:00:00 00:10:00 00:20:00 00:30:004
5
6
Time (HH:MM:SS)
o C
Toutside
HIL Test
HIL Test
(a)
(b)
Outline• Intelligent control lab of PowerLabDK
• Wind power in Denmark
• DFR control logics
• Heat pump model
• HIL test
• Conclusions
• The DFR technology has been developed to utilize the demandside resources to provide fast reserves needed in the futurerenewable based power system.
• The DFR technology has been tested by offline simulations in theprevious work.
• The real time HIL tests were conducted to verify the effectivenessof the DFR technology.
• The HIL test results show that the DFR technology cansuccessfully arrest the system frequency and illustrate the efficacyof the SmartBox.
Conclusions
21 | Corporate Presentation, September 20, 2016
Thank you for your attention