Specifications

Description: The reason for establishing a standard for the Microgrid Energy Management System (MEMS) is to enable interoperability of the different controllers and components needed to operate the MEMS through cohesive and platform-independent interfaces.

Control architecture for high-power electronics from power semiconductor device levels to the power system level is defined and characterized. Coverage includes the application of power electronics in the areas of Power Quality/Custom Power, Flexible AC Transmission Systems (FACTS), High Voltage DC Transmission (HVDC), Distributed Generation, Energy Storage applications, etc. with a power range from hundreds of kW to thousands of MW, but with emphasis on the 1 MW to hundreds of MW.

Description: Terms currently in use in the field of stationary batteries are defined in this standard. This standard does not include terms specific to battery manufacturing activities or to nonstationary battery applications such as motive, portable, marine, or other such applications.

A method for defining the electrical load supplied by a nickel-cadmium battery and for sizing the battery to supply that load is described in this recommended practice.

Description: The electrical interfaces among the components comprising the auxiliary power systems and their electrical interface with other train-borne systems are described.

1.1
This Standard applies to ac and dc type power conversion equipment (PCE) that
a) is of dry or liquid-filled construction;
b) has a rated voltage not exceeding 1500 V; and
c) is for commercial, industrial, and residential indoor and outdoor use in nonhazardous locations in accordance with the Rules of the Canadian Electrical Code, Part I.
1.2
Clauses 1 to 6 are general, and apply, unless otherwise noted, to all PCE.

This part of IEC 60896 is applicable to lead-acid cells and batteries which are designed for service in fixed locations (i.e. not habitually to be moved from place to place) and which are permanently connected to the load and to the d.c. power supply. Batteries operating in such applications are called "stationary batteries".



Any type or construction of lead-acid battery may be used for stationary battery applications. This part 11 of the standard is applicable to vented types only.



The object of this standard is to specify general requirements and the main characteristics, together with corresponding test methods associated with all types and construction modes of lead-acid stationary batteries, excluding valve-regulated types.



Recommendations on the use of tests for stationary battery application are given in Table A.1.



Recommendations relating the type of cell or monobloc to the use of tests are given in Table A.2.



Statements and claims of basic performance data by the manufacturer shall correspond to those tests.



The tests may also be used for type qualification. 

Abstract: Specifies requirements for the installation of vented secondary batteries permanently installed in buildings.
Scope:

IEEE Std 2030 provides alternative approaches and best practices for achieving smart grid interoperability. It is the first all-encompassing IEEE standard on smart grid interoperability providing a roadmap directed at establishing the framework in developing an IEEE national and international body of standards based on cross-cutting technical disciplines in power applications and information exchange and control through communications.

This project aims at the standardization of the microgrid design and planning process, the technical requirement specification of microgrid design and the evaluation of the microgrid planning scheme. The implementation of the proposed recommended practice will enhance the safe, reliable and economic operation of microgrid.