Standard
Standard
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Technical committeeTypeAcronymIEEE 2030.6-2016CommitteePublished year2016KeywordsDescription
A framework for monitoring the effects and evaluating comprehensive benefits of demand response programs is proposed in this guide. From perspectives of ex-ante and ex-post evaluation, this guide introduces the evaluation processes on demand response effects with its comprehensive benefits and implemented calculation methods in detail. This guide could be applied in various electricity market structures to provide utilities with the references for the planning, design, implementation, and post-evaluation of demand response programs.
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Technical committeeTypeAcronymIEEE 2030.5-2018CommitteePublished year2018KeywordsDescription
The application layer with TCP/IP providing functions in the transport and Internet layers to enable utility management of the end user energy environment, including demand response, load control, time of day pricing, management of distributed generation, electric vehicles, etc. is defined in this standard. Depending on the physical layer in use (e.g., IEEE 802.15.4™, IEEE 802.11™, IEEE 1901™, IEEE 1901.2™), a variety of lower layer protocols may be involved in providing a complete solution. Generally, lower layer protocols are not discussed in this standard except where there is direct interaction with the application protocol. The mechanisms for exchanging application messages, the exact messages exchanged including error messages, and the security features used to protect the application messages are defined in this standard. With respect to the Open Systems Interconnection (OSI) network model, this standard is built using the four layer Internet stack model. The defined application profile sources elements from many existing standards, including IEC 61968 and IEC 61850, and follows a RESTful architecture (Fielding [B3]) using IETF protocols such as HTTP. (Additional files for downloads can be found at https://standards.ieee.org/content/dam/ieee-standards/standards/web/dow…)
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Technical committeeTypeAcronymIEEE 2030.5-2013CommitteePublished year2013KeywordsDescription
The 'APPLICATION' layer with TCP/IP providing functions in the 'TRANSPORT' and 'INTERNET' layers is defined in this standard. Depending on the physical layer in use (e.g., IEEE 802.15.4(TM), IEEE 802.11(TM), IEEE 1901(TM)), a variety of lower layer protocols may be involved in providing a complete solution. Generally, lower layer protocols are not discussed in this standard except where there is a direct interaction with the application protocol. This standard defines the mechanisms for exchanging application messages, the exact messages exchanged including error messages, and the security features used to protect the application messages. With respect to the OSI network model, this standard is built using the four-layer Internet stack model. The defined application protocol is an IEC 61968 common information model [61968] profile, mapping directly where possible, and using subsets and extensions where needed, and follows an IETF RESTful architecture [REST]. (NOTE: additional files for this standard is available at http://standards.ieee.org/downloads/2030.5/)
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Technical committeeTypeAcronymIEEE 2030.3-2016CommitteePublished year2016Description
Applications of electric energy storage equipment and systems (ESS) for electric power systems (EPSs) are covered. Testing items and procedures, including type test, production test, installation evaluation, commissioning test at site, and periodic test, are provided in order to verify whether ESS applied in EPSs meet the safety and reliability requirements of the EPS. Grid operators, ESS manufactures, and ESS operators are for whom this standard is established.
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Technical committeeTypeAcronymIEEE 2030.2.1-2019CommitteePublished year2019KeywordsDescription
Application of this standard includes: (1) Stationary battery energy storage system (BESS) and mobile BESS; (2) Carrier of BESS, including but not limited to lead acid battery, lithiumion battery, flow battery, and sodium-sulfur battery; (3) BESS used in electric power systems (EPS). Also provided in this standard are alternatives for connection (including DR interconnection), design, operation, and maintenance of stationary or mobile BESS used in EPS. Introduction, overview, and engineering issues related to the BESS are given.
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Technical committeeTypeAcronymIEEE 2030.2-2015CommitteePublished year2015KeywordsDescription
This guide applies the smart grid interoperability reference model (SGIRM) process (IEEE Std 2030™-2011) to energy storage by highlighting the information relevant to energy storage system (ESS) interoperability with the energy power system (EPS). The process can be applied to ESS applications located on customer premises, at the distribution level, and on the transmission level (i.e., bulk storage). This guide provides useful industry-derived definitions for ESS characteristics, applications, and terminology that, in turn, simplify the task of defining system information and communications technology (ICT) requirements. As a result. these requirements can be communicated more clearly and consistently in project specifications. This guide also presents a methodology that can be used for most common ESS projects to describe the power system, communications, and information technology (IT) perspectives based on the IEEE 2030™ definitions. From this framework, a seemingly complex system can be more clearly understood by all project stakeholders. Emerging cybersecurity requirements can also be incorporated into the framework as appropriate. Additionally, this guide provides the templates that can be used to develop requirements for an ESS project and goes through several real-world ESS project examples step by step.
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Technical committeeTypeAcronymIEEE 1899-2017CommitteePublished year2017KeywordsDescription
The ac/dc substation control equipment, pole control equipment, protection equipment, and auxiliary secondary equipment of high-voltage direct-current (HVDC) transmission systems are the focus of this guide. Based on analyzing the existing HVDC transmission projects, specifications for structure, configuration, performance and test of HVDC control and protection equipment, which could be applied to HVDC transmission system with the voltage range up to and including 800 kV are provided in this guide.
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Technical committeeTypeAcronymIEEE 1898-2016CommitteePublished year2016KeywordsDescription
Outdoor and indoor composite station post insulators used in high-voltage direct-current power transmission systems are covered in this standard. The composite station post insulators covered by this standard consist of a load-bearing insulating core (or tube), a housing (outside the insulating solid core or tube) made of elastomer material (e.g., silicone or ethylene-propylene), and end fittings attached to the insulating core (or tube).
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Technical committeeTypeAcronymIEEE 1854-2019CommitteePublished year2019KeywordsDescription
Important smart distribution applications are categorized, descriptions of the critical functions involved are developed, important components of these systems are defined, and examples of the systems that can be considered as part of distribution management systems or other smart distribution systems are provided in this guide.
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Technical committeeTypeAcronymIEEE 1834-2019CommitteePublished year2019KeywordsDescription
As a significant part of wind turbine, the rotor system of wind turbine has the functions of transforming wind energy, and balancing power, load and noise, it is critical to the wind turbine safety and economical operation. A rotor system consists of blade, hub, pitch system and yaw system. A technical supervision code for each part of the rotor system to improve the safety and normal operation is specified in this standard.
Technology