TIA Smart Grid Standardization Activities - GSC-15

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DOCUMENT #:
GSC15-PLEN-91
FOR:
Presentation
SOURCE:
TIA
AGENDA ITEM:
6.11
CONTACT(S):
David Su (david.su@nist.gov)
Steve Whitesell (swhitesell@vtech.ca)
Randy Ivans (randolph.j.ivans@us.ul.com)
Anthony Noerpel (anthony.noerpel@hughes.com)
Smart Grid Standardization Activities
David Su
National Institute of Standards and
Technology
Global Standards Collaboration (GSC)
GSC-15
U.S. Smart Grid Focused Areas
 Wide-area situational awareness: Monitoring and display of power-system
components and performance across interconnections and wide geographic
areas in near real-time
 Demand response: Mechanisms and incentives for business and residential
customers to cut energy use during times of peak demand.
 Electric storage: Means of storing electric power, directly or indirectly
 Electric transportation: Refers, primarily, to enabling large-scale of plug-in
electric vehicles (PEVs)
 Advanced metering infrastructure (AMI): Primary means for utilities to
interact with meters at customer sites.
 Distribution Grid Management: Maximizing performance of feeders,
transformers, and other components of networked distribution systems and
integrating with transmission systems and customer operations.
 Cyber Network Security
2
NIST Three Phase Plan for
Smart Grid Interoperability
PHASE 1
Identify an initial set of
existing consensus
standards and develop a
roadmap to fill gaps
 NIST role
PHASE 2
Establish Smart Grid
Interoperability Panel (SGIP) publicprivate forum with governance for
ongoing efforts
Summer 2009 workshops
NIST Interoperability
Framework 1.0 Draft Smart Grid
Released Sept 2009 Interoperability
Panel established
Nov 2009
2009
PHASE 3
Conformity
Framework
(includes Testing
and Certification)
NIST Interoperability
Framework 1.0
Released Jan 2010
2010
now
3
NIST Oversight
Smart Grid Interoperability Panel Structure
Stakeholder
Category
Members (22)
SGIP
Standing
Committee
Members (2)
At large
Members (3)
Ex Officio
(non-voting)
Members
SGIPGB
Smart Grid
Identified
Standards
One Organization,
One Vote
(About 600 org’s; almost 1600
persons participating including
international organizations)
Priority
Action
Plans
Use Cases
Requirements
Standards
Descriptions
Standing
Committees
Working
Groups
Architecture,
Test & Certification,
Cyber Security
Conceptual Model
SGIP
Products (IKB)
- Open, transparent body
- Representation from all smart grid stakeholder groups
- Open to any materially interested stakeholder organizations
- Not dominated by any one group
4
Smart Grid
 Morgan Stanley Research estimates the
opportunity in the Smart Grid market will grow
from $20B in 2008, to $40B by 2013, and $100B
by 2030
5
Highlight of TIA Activities (1)
 TIA is a voting member of the Smart Grid Interoperability
Panel
• TIA provided NIST with list of wireless standards relevant to network for
smart grid.
 TIA participates in the activities of the SGIP Priority Action
Group on wireless protocols (PAP02) to develop guidelines
for use of wireless protocols for smart grid applications.
• TR-45.5 provided characteristics for wireless protocols to SGIP
PAP02 regarding evaluation of wireless technologies for cdma2000
and HRPD technologies
•
“It is shown that the cdma2000 1x and HRPD systems can easily
handle the Wireless Wide Area Network traffic created by the use
cases under the heaviest load”
• TR45.3 input IMT-2000 TDMA-SC parameters to the NIST Smart
Grid work by means of its TDMA-SC partner ATIS WTSC.
6
Highlight of TIA Activities (2)
 TIA is developing an access agnostic set of M2M protocols
in Committee TR-50 which can be used for smart grid
devices.
 TIA is developing a standard in TR-41 for immunity to
voltage surges that smart grid equipment may encounter
as a result of lightning strikes.
7
Highlight of TIA Activities (3)
 TR-34 Satellite Communications in the Smart Grid
• GMR-1 3G (TIA, ETSI, ITU)




Mobile Satellite Services standard
Defined for L-band and S-band
3GPP satellite Access stratum
North American Coverage plus international
• Family SL (ETSI)




Mobile Satellite Services standard
Defined for L-band and S-band
3GPP satellite Access stratum
Global Coverage
8
Highlight of TIA Activities (4)
 TR-34 Satellite Communications in the Smart Grid
• IPoS/DVB-S2 (TIA, ETSI, ITU, DVB)
 Fixed Satellite Services standard
 Extended for mobile applications
 North American Coverage plus international
• RSM-A (TIA, ETSI, ITU)
 Fixed Satellite Services standard
 Extended for mobile applications
 CONUS coverage
9
Environmental/Energy Activities
 Dept of Energy (DoE) / Smart Grid
• TIA filing with DoE on how to use smart grid stimulus funds—the
members seemed most interested in asking for a technology
neutral approach (don’t favor/fund one particular architecture or
technology over another) and also urged that consumers’ should
have access to data related to energy usage inside their homes
• TIA will be submitting additional information to DoE and DoE is
interested in participating in roundtables, lunches, and other
potential events where TIA members can continue to dialogue and
exert influence over decision making in the agency.
10
Environmental/Energy Activities
 California PUC Smart Grid Order
• TIA submitted comments to the CA PUC(Public Utilities
Commission) encouraging a federal approach to
identification of standards best practices rather than a
California-specific approach, and also advocated for
flexibility in smart grid deployment plans to allow for
adoption of newer technologies by utilities
11
Challenges
 How can the SDOs coordinate their work on Smart
Grid standards to avoid duplication of efforts and
harmonize incompatible specifications
12
Next Steps/Actions
 Continued focus on development of standards to
support the Smart Grid
13
Proposed New Resolution
 TIA supports ISACC proposal for new resolution
for Smart Grid
 TIA has submitted contribution with recommended
modifications to the ISACC draft resolution.
14
Summary of Presentations (1)





Many countries have initiated Smart Grid activities, including China, EU, Japan,
Korea and the U.S. Each may have different scopes and approaches due to
differences in regional requirements.
Smart Grids are an opportunity for the ICT industry. Partnership and
cooperation between power and ICT companies are vital to the success of the
smart grid story.
Key areas of work: communications and networking, data management,
privacy, and cyber security.
NIST works under EISA mandate to identified standards gaps and ensure
interoperability. The SGIP is working with stakeholders to develop/harmonize
standards. Many SDOs are SGIP members ITU, IEC, ATIS, TIA, IETF, IEEE.
ETSI work on EU M/411 Smart Metering mandate to build standards for
European smart meters, allowing interoperability and Consumer actual
consumption awareness.
15
Summary of Presentations (2)






ATIS and TIA worked with SGIP Priority Action Plan on Wireless to
characterize wireless protocols and develop guidelines for use these protocol
in smart grid applications.
Korea SG standards organizations: Standardization Committee for SG, SG
Standards Forum, SG ICT Convergence Forum, WG 2142.
ITU-T formed a Focus Group on Smart Grid, “ …to collect and document
information and concepts that would be helpful for developing
Recommendations to support smart grid from a telecommunication/ICT
perspective.”
Challenges: better partnership between power and ICT industry; multiplicity of
standards, duplication of work, etc.
Needs stronger cooperation and collaboration among national, regional and
international activities that relate to standardization in the field of "Smart Grids
and ICT”
Proposal recommending new resolution for Smart Grid
Supplementary Slides
17
TR-41 Smart Grid Standard
 Standard on immunity to voltage surges that smart grid equipment may
encounter as a result of lightning strikes
• SG equipment may be connected to both the ac power grid and a metallic
communications network (Ethernet, telephone line, etc.)
• The communications network is likely to have a ground connection located
somewhere other than where the neutral wire for 120/240 V power entering the
premises is grounded.
• A lightning surge in the nearby vicinity of the equipment can produce a
momentary increase in the voltage on one of the ground connections (i.e., a
“ground potential rise”) that does not occur on the other.
• This momentary ground potential rise can result in a large voltage surge occurring
between the power and communication ports of the equipment, a surge which
the equipment must be able to withstand if it is to continue functioning as
intended.
18
Satellite Communications
Applications and Advantages
 Dispatch, maintenance and emergency
•
Repair crews from different regions can have common and reliable communications
even to support recovery from devastating natural disasters such as Katrina.
 Advanced metering infrastructure
•
•
Communications from remote locations not reliably or economically served by other
means of communications
Backhaul of Aggregated smart meter traffic
 Monitoring remote sites
•
Generation, transmission line load and power factor substations, distribution
automation
 Backup, redundancy, reliability, availability
•
•
•
Ubiquity – uniform coverage across North America
Independent link availability and reliability for redundancy
Internet access
19
Satellite Communications
Example: Aggregation for wireless local area networks
Satellite
Redundant or primary link to WAN
Satellite modem
/wireless coordinator
end devices
and routers
smart
meter
smart
meter
Router
Router
smart
meter
smart
meter
smart
meter
smart
meter
smart
meter
smart
meter
20
NIST-identified Standards for
Implementation
 A list of 31 standards and specifications for which NIST believes widest
stakeholder consensus exists http://collaborate.nist.gov/twikisggrid/bin/view/_SmartGridInterimRoadmap/SGR1Standards
They are identified using the following criteria:
• Standard was supported by a standards development organization (SDO) or via
an emergent SDO process.
• Standard is also supported by a users’ community.
• Standard is directly relevant to the Use Cases analyzed for the Smart Grid .
• Consideration was given to those standards with a viable installed base and
vendor community.
 50 additional standards (set) for further review, subject to necessary
modifications or review by application requirements
21
Smart Grid Stakeholders
1
2
3
4
5
6
7
8
9
10
11
Appliance and consumer electronics
providers
Commercial and industrial equipment
manufacturers and automation vendors
Consumers – Residential, commercial,
and industrial
Electric transportation industry
Stakeholders
Electric utility companies – Investor
Owned Utilities (IOU)
Electric utility companies - Municipal
(MUNI)
Electric utility companies - Rural Electric
Association (REA)
Electricity and financial market traders
(includes aggregators)
12
13
Power equipment manufacturers and
vendors
Professional societies, users groups, and
industry consortia
14
R&D organizations and academia
15
Relevant Federal Government Agencies
16
Renewable Power Producers
17
Retail Service Providers
18
Standard and specification development
organizations (SDOs)
19
State and local regulators
20
Testing and Certification Vendors
21
Transmission Operators and Independent
System Operators
22
Venture Capital
Independent power producers
Information and communication
technologies (ICT) Infrastructure and
Service Providers
Information technology (IT) application
developers and integrators
22
22
Smart Grid Will Use International Standards
•ISO/IEC/ITU
•IETF
•IEEE/SAE/ISA
•Global consortia
23
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