33.200 遥控、遥测 标准查询与下载

GB/T 11468-1989 265无线电高度表

本标准规定了265无线电高度表（以下简称高度表）的主要性能要求、环境要求、试验方法和检验规则以及标志、包装、运输、贮存。 本标准适用于265无线电高度表。

265 Radio altimeter

GB/T 9411-1988 机载指点信标接收机性能要求

本标准规定了75MHz机载指点信标接收机的性能要求，作为制订机载指点信标接收机产品标准的依据。

Preformance requirements for airborne marker beacon receiver

GB/T 9392-1988 船用卫星/奥米加组合导航仪 通用技术条件

本标准规定了“船用卫星/奥米加组合导航仪”通用的技术性能，试验方法，验收规则及标志、包装、运输和贮存要求； 本标准适用于“船用卫星/奥米加组合导航仪”（以下简称设备），是制订产品标准的依据。

General specification for marine satellite-omega integrated navigator

GB/T 9391-1988 船用雷达技术要求和使用要求 测试方法和要求的测试结果

本标准适用于船用导航雷达，规定了性能要求及其鉴定检验。 注：第一篇是以国际海事组织（IMO）A.477（XII）决议《船用雷达性能标准》为基础的。凡含义与IMO决议相同的条文均用黑体字印出。

Shipborne radar,technical and operational requirements, Mcthod of testing and required test results

GB/T 9390-1988 导航术语

本标准规定了导航专业的基本术语，作为导航专业制订标准，编制技术文件，编写和翻译专业手册、教材及书刊的依据。凡本标准中未作规定的导航术语，可在各类有关标准中规定。

Terminology for navigation

GB/T 3784-1983 雷达名词术语

本标准适用于雷达所用名词术语，并与IECPublication50（60）“国际电工词汇”（International E1ectrotechnica1Vocabulary）1970年第二版第七章“无线电定位和无线电导航”（Radiolocationandradionavigation）第3节“雷达”（Radar）完全一致。

The terms and definitions related to radar

BS EN IEC 61970-457:2024 能源管理系统应用程序接口 (EMS-API) 动态配置文件

Energy management system application program interface (EMS-API) - Dynamics profile

BS EN IEC 61970-302:2024 能源管理系统应用程序接口 (EMS-API) 通用信息模型 (CIM) 动态

Energy management system application program interface (EMS-API) - Common information model (CIM) dynamics

EN IEC 61970-457:2024 能源管理系统应用程序接口 (EMS-API) 第457部分：动态配置文件

IEC 61970-457:2024 specifies a standard interface for exchanging dynamic model information needed to support the analysis of the steady state stability (small-signal stability) and/or transient stability of a power system or parts of it. The schema(s) for expressing the dynamic model information are derived directly from the CIM, more specifically from IEC 61970-302. The scope of this document includes only the dynamic model information that needs to be exchanged as part of a dynamic study, namely the type, description and parameters of each control equipment associated with a piece of power system equipment included in the steady state solution of a complete power system network model. Therefore, this profile is dependent upon other standard profiles for the equipment as specified in IEC 61970-452: CIM static transmission network model profiles, the topology, the steady state hypothesis and the steady state solution (as specified in IEC 61970-456: Solved power system state profiles) of the power system, which bounds the scope of the exchange. The profile information described by this document needs to be exchanged in conjunction with IEC 61970-452 and IEC 61970-456 profiles’ information to support the data requirements of transient analysis tools. IEC 61970-456 provides a detailed description of how different profile standards can be combined to form various types of power system network model exchanges. This document supports the exchange of the following types of dynamic models: • standard models: a simplified approach to exchange, where models are contained in predefined libraries of classes interconnected in a standard manner that represent dynamic behaviour of elements of the power system. The exchange only indicates the name of the model along with the attributes needed to describe its behaviour. • proprietary user-defined models: an exchange that would provide users the ability to exchange the parameters of a model representing a vendor or user proprietary device where an explicit description of the model is not described in this document. The connections between the proprietary models and standard models are the same as described for the standard models exchange. Recipient of the data exchange will need to contact the sender for the behavioural details of the model. This document builds on IEC 61970-302, CIM for dynamics which defines the descriptions of the standard dynamic models, their function block diagrams, and how they are interconnected and associated with the static network model. This type of model information is assumed to be pre-stored by all software applications hence it is not necessary to be exchanged in real-time or as part of a dynamics model exchange. This second edition cancels and replaces the first edition published in 2021. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: a) The majority of issues detected in IEC 61970-302:2018 and fixed in IEC 61970-302:2022 led to update of this document; b) IEEE 421.5-2016 on Excitation systems is fully covered; c) IEEE turbine report from 2013 was considered and as a result a number of gas, steam and hydro turbines/governors are added; d) IEC 61400-27-1:2020 on wind turbines is fully incorporated; e) WECC Inverter-Based Resource (IBR) models, Hybrid STATCOM models and storage models are added; f) The user defined models approach was enhanced in IEC 61970-302:2022 adding a model which enables modelling of a detailed dynamic model. This results in the creation of two additional pr

Energy management system application program interface (EMS-API) - Part 457: Dynamics profile

EN IEC 61970-302:2024 能源管理系统应用程序接口 (EMS-API) 第302部分：通用信息模型 (CIM) 动态

IEC 61970-302:2024 specifies a Dynamics package which contains part of the CIM to support the exchange of models between software applications that perform analysis of the steady-state stability (small-signal stability) or transient stability of a power system as defined by IEEE / CIGRE, Definition and classification of power system stability IEEE/CIGRE joint task force on stability terms and definitions. The model descriptions in this document provide specifications for each type of dynamic model as well as the information that needs to be included in dynamic case exchanges between planning/study applications. The scope of the CIM Dynamics package specified in this document includes: • standard models: a simplified approach to describing dynamic models, where models representing dynamic behaviour of elements of the power system are contained in predefined libraries of classes which are interconnected in a standard manner. Only the names of the selected elements of the models along with their attributes are needed to describe dynamic behaviour. • proprietary user-defined models: an approach providing users the ability to define the parameters of a dynamic behaviour model representing a vendor or user proprietary device where an explicit description of the model is not provided by this document. The same libraries and standard interconnections are used for both proprietary user-defined models and standard models. The behavioural details of the model are not documented in this document, only the model parameters. • A model to enable exchange of models’ descriptions. This approach can be used to describe user defined and standard models. • A model to enable exchange of simulation results. This second edition cancels and replaces the first edition published in 2018. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: a) The majority of issues detected in IEC 61970-302:2018 are addressed; b) IEEE 421.5-2016 on Excitation systems is fully covered; c) The IEEE turbine report from 2013 was considered and as a result a number of gas, steam and hydro turbines/governors are added; d) IEC 61400-27-1:2020 on wind turbines is fully incorporated; e) WECC Inverter-Based Resource (IBR) models, Hybrid STATCOM models and storage models are added; f) The user defined models are enhanced with a model which enables modelling of detailed dynamic model; g) A model to enable exchange of simulation results is added; h) The work on the HVDC models is not complete. The HVDC dynamics models are a complex domain in which there are no models that are approved or widely recognised on international level, i.e. there are only project-based models. At this stage IEC 61970-302:2022 only specifies some general classes. However, it is recognised that better coverage of HVDC will require a further edition of this document; i) Models from IEEE 1547-2018 "IEEE Standard for Interconnection and Interoperability of Distributed Energy Resources with Associated Electric Power Systems Interfaces" are added. j) Statements have been added to certain figures, tables, schemas, and enumerations throughout the document that indicate that they are reproduced with the permission of the UCA International User Group (UCAIug). These items are derived from the CIM.

Energy management system application program interface (EMS-API) - Part 302: Common information model (CIM) dynamics

GSO IEC TR 61850-90-11:2024 用于电力公用事业自动化的通信网络和系统 第90-11部分：基于 IEC 61850 的应用的逻辑建模方法

IEC TR 61850-90-11:2020(E), which is a Technical Report, describes the methodologies for the modelling of logics for IEC 61850 based applications in power utility automation. In particular, it describes the functional view of logic based on existing logical nodes for generic process automation and the operational modes of the logic. Furthermore it includes the specification of the standard language to be applied to specific the logic as well as the related data exchange format between engineering tools and their application as well as the mapping of logic elements to IEC 61850 data types. The examples or use cases given in this document are based on the class model introduced in IEC 61850-7-1 and defined in IEC 61850-7-3. The logical node and data names used in this document are defined in IEC 61850-7-4, the services applied in IEC 61850-7-2. The naming conventions of IEC 61850-7-2 are applied in this document also. If extensions are needed in the application examples, the normative naming rules for multiple instances and private, compatible extensions of Logical Node (LN) Classes and Data Object Names defined in IEC 61850-7-1 are considered. This document describes the use of IEC 61850 extensions for modelling logics, therefore it implies some tutorial material. However it is advisable to read IEC 61850-6 and IEC 61850-7-1 in conjunction with IEC 61850-7-3 and IEC 61850-7-2 first and IEC 61131-3 as reference for the programming language of logic. The different logics included in any IED in an IEC 61850 based system can be classified into two groups: • Fixed Logic: These logics are predefined mostly for critical and complex functions. They are typically included in the IED´s defined application, potentially implemented in software, firmware or hardware, and are not modifiable with IEC 61850 tools and services. These logics are implementation specific. Fixed logic is out of the scope of this document. • Editable Logic: These are user configurable / programmable logics which shall be modelled through IEC 61850 configuration tools and be accessible by IEC 61850 services. These logics can be application specific. The major goal of this document is to adopt the given functionality of an IED to fit to specific application function demands. This is to provide a definition of the methodology for describing and exchanging logics using an IEC 61850 compatible solution. As a benefit the same logic description will be valid and vendor-independent, so it could be used for different IEDs. It is up to the tools to understand this standard description in order to be able to manipulate the logics and to properly configure the IEDs. Graphical representation of logic is currently out-of-scope of the IEC 61850 series, even if it is part of the PLCopen XML specification. The representation is subject to the engineering tools. Modelling logics requires some extension of the currently defined data model and / or an extension of the content in the SCL files which is described and which needs to be considered in later editions of IEC 61850-6 and IEC 61850-7-4.

Communication networks and systems for power utility automation - Part 90-11: Methodologies for modelling of logics for IEC 61850 based applications

GSO IEC TR 61850-90-13:2024 用于电力公用事业自动化的通信网络和系统 第90-13部分：确定性网络技术

IEC TR 61850-90-13:2021(E), which is a Technical Report, provides information, use cases, and guidance on whether and how to use deterministic networking technologies. Furthermore, this document comprises technology descriptions, provides guidance how to achieve compatibility and interoperability with existing technologies, and lays out migration paths. It will separate the problem statement from the possible solutions.

Communication networks and systems for power utility automation - Part 90-13: Deterministic networking technologies

GSO IEC TR 61850-90-14:2024 用于电力公用事业自动化的通信网络和系统 第90-14部分：使用 IEC 61850 进行 FACTS（灵活交流输电系统）、HVDC（高压直流）输电和电力转换数据建模

IEC TR 61850-90-14:2021(E), which is a technical report, specifies the information model of devices and functions related to systems of power utility automation, specifically related to FACTS (Flexible AC Transmission Systems) and Power Conversion applications. The IEC 61850-90-14 information model standard utilizes existing IEC 61850-7-4 logical nodes where possible, but also defines specific logical nodes where needed. Specifically, the scope of this document: • Covers communication between control system of FACTS, HVDC and Power Conversion and SCADA and HMI systems • Includes the data model for FACTS, HVDC and Power conversion devices • Does not cover Protection relays • Does not cover process bus • Does not cover valve communication

Communication networks and systems for power utility automation - Part 90-14: Using IEC 61850 for FACTS (flexible alternate current transmission systems), HVDC (high voltage direct current) transmission and power conversion data modelling

GSO IEC TR 61850-90-16:2024 电力公用事业自动化中的通信网络和系统 第90-16部分：智能能源自动化的系统管理要求

IEC TR 61850-90-16:2021(E) which is a technical report, specifies the mechanisms for the system management of Smart Grid Devices as IEC 61850 equipment in power utility automation as well as telecommunication and cybersecurity equipment. System Management of Smart Grid Devices or Smart Grid Device Management refers to functionalities that are not directly linked to the operational role of the equipment (which for grid automation equipment would be to protect and allow remote supervision and control on the grid) but allow it to perform its operational functions in the best conditions possible. The main functions of Smart Grid Device Management can be categorized as illustrated in Figure 1 and described below. These actions being available from remote information systems, they affect system automation functions, telecommunication functions and cybersecurity functions as these three categories are interacting in a Smart grid Device or system. The Smart Grid domain has been chosen for these use cases, including distributed energy resources. This content is expected to be applicable to other domains, such as industrial automation domain and grid user domain.

Communication networks and systems in power utility automations - Part 90-16: Requirements of system management for Smart Energy Automation

IEC 61970-302:2024 能源管理系统应用程序接口（EMS-API）.第302部分:公共信息模型（CIM）动力学

Energy management system application program interface (EMS-API) - Part 302: Common information model (CIM) dynamics

GSO IEC TR 61850-90-8:2024 用于电力公用事业自动化的通信网络和系统 第90-8部分：电动交通的对象模型

IEC TR 61850-90-8:2016(E) shows how IEC 61850-7-420 can be used to model the essential parts of the E-Mobility standards related to Electric Vehicles and Electric Vehicle Supply Equipments (IEC 62196, IEC 61851, IEC 15118) and the Power system (IEC 61850-7-420), in order to secure a high level of safety and interoperability.

Communication networks and systems for power utility automation - Part 90-8: Object model for E-mobility

GSO IEC TR 61850-90-12:2024 电力公用事业自动化通信网络和系统 第90-12部分：广域网工程指南

IEC TR 61850-90-12:2020, which is a Technical Report, is intended for an audience familiar with electrical power automation based on IEC 61850 and related power system management, and particularly for data network engineers and system integrators. It is intended to help them to understand the technologies, configure a wide area network, define requirements, write specifications, select components, and conduct tests. This document provides definitions, guidelines, and recommendations for the engineering of WANs, in particular for protection, control and monitoring based on IEC 61850 and related standards. This document addresses substation-to-substation communication, substation-to-control centre, and control centre-to-control centre communication. In particular, this document addresses the most critical aspects of IEC 61850 such as protection related data transmission via GOOSE and SMVs, and the multicast transfer of large volumes of synchrophasor data. The document addresses issues such as topology, redundancy, traffic latency and quality of service, traffic management, clock synchronization, security, and maintenance of the network. This document contains use cases that show how utilities tackle their WAN engineering. This second edition cancels and replaces the first edition published in 2015. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: a) extension of use case with respect to distribution and customer-side applications; b) extensions of wireless access technologies as well as power line communication ones applicable to the above-mentioned use case; c) revisions regarding radio communication technology performance; d) extension of network migration with respect to packet switched network; e) a new mapping of multiprotocol label switching technology to teleprotection.

Communication networks and systems for power utility automation - Part 90-12: Wide area network engineering guidelines

GSO IEC TR 61850-90-10:2024 用于电力公用事业自动化的通信网络和系统 第90-10部分：调度模型

IEC TR 61850-90-10:2017(E) describes scheduling for devices using IEC 61850.

Communication networks and systems for power utility automation - Part 90-10: Models for scheduling

GSO IEC TR 61850-90-9:2024 用于电力公用事业自动化的通信网络和系统 第90-9部分：IEC 61850 在电能存储系统中的使用

IEC TR 61850-90-9:2020(E) describes the IEC 61850 information model for electrical energy storage systems (EESS). Therefore, this document only focuses on storage functionality in the purpose of grid integration of such systems at the DER unit level. Higher level Interactions are already covered in IEC 61850-7-420.

Communication networks and systems for power utility automation - Part 90-9: Use of IEC 61850 for Electrical Energy Storage Systems

T/CAGDE 236-2024 全数字TCP/IP可视门铃

本文件规定了全数字TCP/IP可视门铃的术语与定义、技术要求、试验方法、检验规则和标志、包装、运输、贮存的要求

Digital TCP/IP visual doorbell