The document discusses clean energy microgrids, which are small-scale power grids that can disconnect from the traditional grid and operate autonomously. It provides examples of microgrids at the University of Texas and other locations. Microgrids are owned by customers or third parties and can improve energy reliability and profitability while reducing emissions. The document outlines reasons to implement microgrids including improving asset utilization, avoiding rising utility costs, and increasing control during outages. It also discusses some barriers to microgrid adoption like regulatory reforms and the need for standardization.
Block diagram reduction techniques in control systems.ppt
Clean energy microgrids - Hype or Reality?
1. CLEAN ENERGY MICROGRIDS
Hype or Reality?
Own your power
Energy Management in Buildings and Cities -
Trends, Opportunities & Barriers
April 13th, 2-4 PM, Porter School of Environmental
Studies, Tel Aviv University
2. What is a Microgrid?
Controls load and generation onsite
Includes distribution wires
Connects or disconnects (island) from
central grid with black-start capability
Provides energy 24/7, 365 days a year
2Think Microgrid A Discussion Guide for Policymakers, Regulators and End Users 2014, Energy Efficiency Markets, LLC
4. Who owns them?
Customer or third-party owned
Commercial and industrial areas
Educational campuses
Communities and neighbourhoods
4Think Microgrid A Discussion Guide for Policymakers, Regulators and End Users 2014, Energy Efficiency Markets, LLC
5. The University of Texas microgrid
140MW
100 percent of power
heating and cooling to 150 campus buildings
20 million square feet
Operating 40 years with 99.9998% reliability
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7. Why microgrids?
1. Improves asset profitability
2. Avoids rising costs of main grid
3. Meets rising peak demand at lower cost
4. Control during unplanned outages
5. Reduces carbon emissions
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8. 1. Improves property profitability
Continue to generate revenue regardless of
whether the main grid is operating or not
Utility costs available for resale rather than as a
pass through cost paid to utility
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12. 4. Greater control of supply and costs
Severe weather such as Superstorm Sandy
leading cause of power outages in USA
Losses risen to $200 billion per year in the
last decade, globally
Unplanned outages also due to under
investment, lack of maintenance, substation
and transmission line equipment failures
12Major Power Outages in the US, and around the World IEEE Reliability Society 2009 Annual Technology Report, James McLinn Rel-Tech Group
13. 4. Unplanned outages trends
Major power
outages increasing
everywhere, over
the last 20 years
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Major Power Outages in the US, and around the World IEEE Reliability Society 2009 Annual Technology Report, James McLinn Rel-Tech Group
15. 5. Reduces carbon emissions
Cost effectively lowers carbon emissions by
using waste heat, demand response, solar,
wind, fuel cells and batteries
Improved access to climate change financing,
meets national environmental laws and
emissions reduction targets
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The Micro(grid) Solution to the Macro Challenge of Climate Change
17. Can microgrids operate legally?
South Carolina state
has jurisdiction over
the sale of power
from rooftop solar
panels to a host
Connecticut allows
microgrids to sell
across power across
public streets
17March 2013 Public Utilities Fortnightly article, “Peaceful Co-Existence,” Sara Brown and Paul McCary
18. Why Israel should get onboard
1,437 microgrids worldwide, 13 GW
$40 billion annually by 2020, up from $10 billion
in 2013
Clean energy investment in China, Africa, the US,
Latin America and India $328.9bn in 2015
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Source: Q4 2015 Microgrid Deployment Tracker released by Navigant Research and Bloomberg, January 2016
20. What’s the ROI of microgrids?
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Pay for themselves due to cost savings
Avoidance of transmission upgrade and
Continual operations
Texas U Microgrid, Princeton U MG and many
others have achieved net savings
21. Timing is right
Bankable energy storage (batteries)
Solar PV costs reduced by 95% over 10 years
Improved microgrid power control software (IoT)
Operations and regulations simplified
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23. Barriers to exponential growth
Reform energy, capacity and ancillary markets
Allowed to serve as their own balancing
authority when in island mode
Provide compensation for congestion relief
Recognize value of black start capabilities
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24. Opportunities for Israeli Companies
“it is more economically viable for a hybrid PV-CSP power
plant with Molten Salt storage to operate baseload in
comparison to hybrid PV-diesel” or PV-battery
This is true for Chile and South Africa, North Africa,
Australia, East Africa, India and China
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Solar PV-CSP Hybridisation for Baseload Generation - A Techno-economic Analysis for the Chilean Market - Kevin Larchet, Master of Science Thesis KTH School of
Industrial Engineering and Management Energy Technology
25. Current microgrid R&D activity
US DoE goals for R&D activities
reducing outage time by more than 98% at a cost
comparable to non-integrated baseline solutions
reducing emissions by more than 20% and
improving system energy efficiencies by more
than 20% by 2020.
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26. Microgrid R&D focus
Planning and design
Operations and control
Standardization of design, contracting,
installation, security, and operation
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The Smart Power Infrastructure Demonstration and Energy Reliability and Security (SPIDERS) project a Joint Capability Technology Demonstration between
Departments of Energy, Defense and Homeland Security (at SANDIA and NREL)
27. Project Example
Project Location
Simulation Model inputs
Load Profile
Location Abuja Nigeria
Latitude 9 degrees 4.59 minutes North
Longitude 9 degrees 4.59 minutes North
Time zone Africa/Lagos
Data source Synthetic
Daily noise 5%
Hourly noise 5%
Scaled annual average load 25,131.744 kWh/d
Scaled peak load 2,786.1260kW
Load factor 37.58%
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30. Sources
• http://microgridknowledge.com/mice-microgrids-profile-one-us-largest-microgrids/
• http://www.csemag.com/single-article/case-study-microgrid-at-princeton-university/a852c6c36420f738c8ecf66de7aa3dd1.html
• http://www.demandresponsesmartgrid.org/resources/Documents/Case%20Studies/SDGE%20Borrego%20Springs%20Case%20Study%20FINAL.
pdf
• Aggregating Levelized Cost Functions In Microgrids For Transmission Grid Operation Jhi-Young Joo, Sriram Raghavan, and Pourya Shamsi
Department of Electrical and Computer Engineering Missouri University of Science and Technology Rolla, Missouri
• Unplanned outages according to a 2008 estimate by the World Energy Council
• According to a GE report “SAN DIEGO – February, 2015
• http://www.hobokennj.org/2013/06/city-of-hoboken-us-department-of-energy-nj-board-of-public-utilities-pseg-partner-to-develop-resilient-
electric-grid/
• ECONOMIC BENEFITS OF INCREASING ELECTRIC GRID RESILIENCE TO WEATHER OUTAGES Executive Office of the President August 2013
• The New Economics of Battery Storage
• http://www.rmi.org/elab_accelerator_2015_hoboken_microgrid_development
• https://building-microgrid.lbl.gov/sites/all/files/santiago_canizares.pdf
• DNV KEMA points out in its August 2013 paper, “Microgrids for Fun and Profit”.
• Costs of Utility Distributed Generators, 1-10 MW Twenty-Four Case Studies 1007760 EPRI
• Backup Power Cost of Ownership Analysis and Incumbent Technology Comparison J. Kurtz, G. Saur, S. Sprik, and C. Ainscough National
Renewable Energy Laboratory Prepared under Task No. H279.1710
• Major Power Outages in the US, and around the World IEEE Reliability Society 2009 Annual Technology Report, James McLinn Rel-Tech Group
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