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Delivery: <= 7 days. True-PDF full-copy in English will be manually translated and delivered via email. GB/T 36006-2018: Control and communication network -- Safety-over-Ether CAT specification Status: Valid
Basic dataStandard ID: GB/T 36006-2018 (GB/T36006-2018)Description (Translated English): Control and communication network -- Safety-over-Ether CAT specification Sector / Industry: National Standard (Recommended) Classification of Chinese Standard: N10 Classification of International Standard: 25.040 Word Count Estimation: 106,153 Date of Issue: 2018-03-15 Date of Implementation: 2018-10-01 Issuing agency(ies): State Administration for Market Regulation, China National Standardization Administration GB/T 36006-2018: Control and communication network -- Safety-over-Ether CAT specification---This is a DRAFT version for illustration, not a final translation. Full copy of true-PDF in English version (including equations, symbols, images, flow-chart, tables, and figures etc.) will be manually/carefully translated upon your order.Control and communicatoin network--Safety-over-EtherCAT specification ICS 25.040 N10 National Standards of People's Republic of China Control and communication network Safety-over-EtherCAT specification (IEC 61784-3-12.2010, Industrialcommunicationnetworks-Profiles- Part 3-12. Functional safety fieldbuses-Additional specifications for CPF12, IDT) Published on.2018-03-15 2018-10-01 implementation General Administration of Quality Supervision, Inspection and Quarantine of the People's Republic of China China National Standardization Administration issued ContentForeword III Introduction IV 1 Scope 1 2 Normative references 1 3 Terms, definitions, symbols, abbreviations and conventions 2 3.1 Terms and Definitions 2 3.1.1 General terms and definitions 2 3.1.2 Additional terms and definitions 6 3.2 Symbols and abbreviations 7 3.2.1 General symbols and abbreviations 7 3.2.2 Additional symbols and abbreviations 7 3.3 Convention 7 4 FSCP12/1 (Safety-over-EtherCAT) Overview 8 5 Overview 9 5.1 External documents providing profile specifications 9 5.2 Security function requirements 9 5.3 Security measures 9 5.4 Secure Communication Layer Structure 10 5.5 Relationship with FAL (and DLL, PhL) 10 5.5.1 Overview 10 5.5.2 Data Type 10 6 Secure Communication Layer Service 11 6.1 FSoE connection 11 6.2 FsoE Cycle 11 6.3 FsoE Service 12 7 Secure Communication Layer Protocol 12 7.1 Security PDU Format 12 7.1.1 Security PDU Structure 12 7.1.2 Security PDU Command 13 7.1.3 Security PDUCRC 14 7.2 FSCP12/1 communication procedures 17 7.2.1 Message period 17 7.2.2 FSCP12/1 Node Status 17 7.3 Response to communication errors 27 7.4 Status Table of the FsoE Master Station 28 7.4.1 FsoE Master Station State Machine 28 7.4.2 Reset Status 32 7.4.3 Session Status 34 7.4.4 Connection Status 38 7.4.5 Parameter Status 43 7.4.6 Data Status 48 7.5 FsoE Slave Status Table 52 7.5.1 FsoE Slave State Machine 52 7.5.2 Reset Status 56 7.5.3 Session Status 59 7.5.4 Connection Status 64 7.5.5 Parameter Status 70 7.5.6 Data Status 76 8 Secure Communication Layer Management 82 8.1 FSCP12/1 Parameter Processing 82 8.2 FsoE communication parameters 82 9 System Requirements 82 9.1 Indicators and Switches 82 9.1.1 Indicator status and flashing frequency 82 9.1.2 Indicators 83 9.2 Installation Guide 84 9.3 Security function response time 84 9.3.1 Overview 84 9.3.2 Determination of FsoE watchdog time 85 9.3.3 Calculation of worst case safety function response time 86 9.4 Duration of the request 87 9.5 Constraints for System Feature Value Calculation 87 9.5.1 Overview 87 9.5.2 Probability considerations 87 9.6 Maintenance 88 9.7 Safety Manual 88 10 Evaluation 89 Appendix A (informative) Additional information on the functional safety communication profile of CPF12 90 Appendix B (informative) CPF12 functional safety profile assessment information 97 Reference 98ForewordThis standard was drafted in accordance with the rules given in GB/T 1.1-2009. This standard uses the translation method equivalent to IEC 61784-3-12.2010 "Industrial Communication Network Profiles Part 3-12. Functional Safety Additional Specifications for Fieldbus CPF12. The documents of our country that have a consistent correspondence with the international documents referenced in this standard are as follows. --- GB 5226.1-2008 Mechanical electrical safety machinery and electrical equipment - Part 1. General technical conditions (IEC 602041. 2005, IDT) --- GB/T 15969.2-2008 Programmable controllers - Part 2. Equipment requirements and testing (IEC 61131-2.2007, IDT) --- GB/T 16657.2-2008 Industrial Communication Network Fieldbus Specification Part 2. Physical Layer Specification and Service Definition (IEC 61158-2.2007, IDT) ---GB/T 17799.2-2003 Electromagnetic compatibility general standard immunity test in industrial environment (IEC 61000-6-2. 1999, IDT) ---GB/T 20438 (all parts) Functional safety of electrical/electronic/programmable electronic safety related systems [IEC 61508 There are some)] This standard has made the following editorial changes. --- Change the standard name to "Control and Communication Network Safety-over-EtherCAT Specification"; --- Modified some formatting formats according to Chinese habits; --- Replace "IEC 61508" with "IEC 61508 series standard", delete the description of the trademark, and the unpublished standard The quasi-current has been released, so delete the footnote content in the original text. This standard was proposed by the China Machinery Industry Federation. This standard is under the jurisdiction of the National Industrial Process Measurement Control and Automation Standardization Technical Committee (SAC/TC124). This standard was drafted. Institute of Mechanical Industry Instrumentation and Instrumentation, Institute of Automation, Chinese Academy of Sciences, Shenyang Institute of Automation, Tsinghua University Xue, Southwest University, Beijing University of Aeronautics and Astronautics, Beijing Heli System Engineering Co., Ltd., Shanghai Automation Instrument Co., Ltd., Shenyang Machine Tool (Group) Design and Research Institute Co., Ltd., Haitian Drive Co., Ltd., Omron Automation (China) Co., Ltd., EtherCAT Technology Association, Germany Beckhoff Automation Co., Ltd. The main drafters of this standard. Wang Shuo, Ding Lu, Gao Jingmei, Wang Chunxi, Yang Zhijia, Wang Xue, Liu Feng, Liu Yanqiang, Luo An, Bao Weihua, Qiao Xiaotong, Yu Shilei, Li Jianri, Yue Wei, Guan Peng, Li Tianbing, Fan Bin, Cheng Geng.IntroductionThe IEC 61158 fieldbus standard and its companion standards IEC 61784-1 and IEC 61784-2 define a set of communication protocols. Implement distributed control of automated applications. Fieldbus technology is now generally accepted and proven to be viable. Therefore, many fieldbus technologies The technology continues to improve, covering areas that have not been standardized, such as real-time, functional safety-related and information security-related applications. This standard is based on the IEC 61508 series of standards, describes the principles of functional safety communication, and is standardized based on IEC 61784-1, IEC 61784-2 and the IEC 61158 series of standards for communication profiles and protocol layers of several secure communication layers (profiles and corresponding protocols), but excluding electricity Gas safety and intrinsic safety aspects. Figure 1 shows the relationship between this standard and the relevant safety and fieldbus standards in the mechanical environment. Note. 6.7.6.4 (high complexity) and 6.7.8.1.6 (low complexity) in GB 28526 specify the relationship between PL (category) and SIL. Figure 1 Relationship between IEC 61784-3 and other standards (mechanical) Figure 2 shows the relationship between this standard and the relevant safety and fieldbus standards in the process environment. a For the specified electromagnetic environment, otherwise see IEC 61326-3-1. Figure 2 Relationship between IEC 61784-3 and other standards (processes) In a safety-related system built according to the IEC 61508 series of standards, the secure communication layer is implemented as part of this layer. The transmission of messages (information) between fieldbus participants of two or more safety-related systems provides the necessary credibility; or on the fieldbus Provides sufficient credibility for safe behavior in fault or failure events. The secure communication layer specified in this standard enables fieldbus to be used for functional safety to achieve safety integrity level (SIL) applications. The SIL level is specified by its corresponding functional safety communication profile. The final SIL of a system is determined by the implementation of the selected functional safety communication profile in the system - functional safety The implementation of the letter profile in standard equipment in accordance with this standard is not sufficient to certify that the device is a security device. This standard describes. --- Implement the basic principles of the IEC 61508 series of standards for safety-related data communication requirements, including possible transmission failures, remediation measures Considerations that affect data integrity; --- Separate descriptions of the functional safety profiles of multiple communication profiles in IEC 61784-1 and IEC 61784-2; --- Security layer extension to the communication services and protocols part of the IEC 61158 series of standards. Control and communication network Safety-over-EtherCAT specification1 ScopeThis standard specifies the secure communication layer (services and protocols) of CPF12 and IEC 61158 type 12 based on IEC 61784-2, and The principle of functional safety communication as defined in IEC 61784-3 is relevant to the secure communication layer in this standard. Note 1. Does not include electrical safety and intrinsic safety aspects. Electrical safety is related to dangers such as electric shock. Intrinsic safety and related to potentially explosive environments The danger is related. This standard defines a mechanism for transmitting security-related messages between participants in a distributed network using fieldbus technology. It meets the functional safety requirements of the IEC 61508 series of standards. These mechanisms can be used in a variety of industrial applications such as process control, manufacturing Mobility and machinery. This standard provides guidance to developers and evaluators of equipment and systems that comply with this standard. Note 2. The final SIL of a system is determined by the implementation of the functional safety communication profile selected in the system---functional safety communication profile Implementations in accordance with this standard in a quasi-device are not sufficient to certify that the device is a secure device.2 Normative referencesThe following documents are indispensable for the application of this document. For dated references, only dated versions apply to this article. Pieces. For undated references, the latest edition (including all amendments) applies to this document. IEC 60204-1 Mechanical electrical safety machinery and electrical equipment - Part 1. General technical conditions (Safetyofmachinery-E- Lectricalequipmentofmachines-Part 1.Generalrequirements) IEC 61000-6-2 Electromagnetic compatibility general standard immunity test in industrial environment (Electromagneticcompatibility (EMC)-Part 6-2. Genericstandards–Immunityforindustrialenvironments) IEC 61131-2 Programmable Controllers Part 2. Equipment Requirements and Tests (Programmablecontrolers-Part 2. Equipmentrequirementsandtests) IEC 61158-2 Industrial Communication Network Fieldbus Specification Part 2. Physical Layer Specification and Service Definition (Industrialcom- municationnetworks-Fieldbusspecifications-Part 2.Physicallayerspecificationandservicedefini- Tion) IEC 61158-3-12 Industrial Communication Network Fieldbus Specification Part 3-12. Data Link Layer Service Definition Type 12 Industrial communication network-Fieldbusspecifications-Part 3-12. Data-linklayerservice definition-Type12elements) IEC 61158-4-12 Industrial Communication Network Fieldbus Specification Part 4-12. Data Link Layer Protocol Specification Type 12 Industrial communication network-Fieldbusspecifications-Part 4-12. Data-linklayerprotocol specification-Type12elements) IEC 61158-5-12 Industrial Communication Network Fieldbus Specification Part 5-12. Application Layer Service Definition Type 12 Element (Industrialcommunicationnetworks-Fieldbusspecifications-Part 5-12. Applicationlayerservice definition-Type12elements) IEC 61158-6-12 Industrial Communication Network Fieldbus Specification Part 6-12. Application Layer Protocol Specification Type 12 Element (Industrialcommunicationnetworks-Fieldbusspecifications-Part 6-12. Applicationlayerprotocol specification-Type12elements) IEC 61326-3-1 Electrical Equipment for Measurement, Control and Laboratory Use - Part 3-1. Safety-related systems and implementation Fully related functional (functional safety) equipment immunity requirements for general industrial applications (Electricalequipmentformeasurement, con- trolandlaboratoryuse-EMCrequirements-Part 3-1. Immunityrequirementsforsafety-relatedsys- Temsandforequipmentintendedtoperformsafetyrelatedfunctions(functionalsafety)-Generalin- Dustrialapplications) IEC 61326-3-2 Electrical Equipment for Measurement, Control and Laboratory Use - Part 3-2. Safety-related Systems and Execution Fully related functional (functional safety) device immunity requirements for industrial applications with specific electromagnetic environments (Electricalequipmentfor Measurement,controlandlaboratoryuse-EMCrequirements-Part 3-2.Immunityrequirementsfor Safety-relatedsystemsandforequipmentintendedtoperformsafetyrelatedfunctions(functionalsafe- Ty)-Industrialapplicationswithspecifiedelectromagneticenvironment) IEC 61508 (all parts) Functional safety of electrical/electronic/programmable electronic safety related systems (Functional safety ofe- Lectrical/electronic/programmableelectronicsafety-relatedsystems) IEC 617842 Industrial Communication Network Profiles Part 2. Additional site totals for real-time networks based on ISO /IEC 8802-3 Line profile (Industrialcommunicationnetworks-Profiles-Part 2.Additionalfieldbusprofilesforreal- timenetworksbasedonISO /IEC 8802-3) IEC 61784-3.2010 Industrial Communication Network Profiles Part 3. Functional Safety Fieldbus General Rules and Profile Definitions (Industrialcommunicationnetworks-Profiles-Part 3. Functionalsafetyfieldbuses-Generalrules Andprofiledefinitions) IEC 61918 communication network installation in industrial communication network industrial environment (Industrialcommunicationnetworks- Instalationofcommunicationnetworksinindustrialpremises) 3 Terms, definitions, symbols, abbreviations and conventions The following terms, definitions, symbols, abbreviations and conventions apply to this document. 3.1 Terms and definitions 3.1.1 General terms and definitions 3.1.1.1 Availability availability The automation system does not have a probability of not meeting system conditions (eg, discontinued production) within a given time. 3.1.1.2 Black channel blackchannel There is no need to obtain a communication channel for design or verification certification in accordance with the IEC 61508 series of standards. 3.1.1.3 Communication channel communicationchannel A logical connection between two terminals within a communication system. 3.1.1.4 Communication system It consists of hardware, software and transmission media to allow the transfer of messages (GB/T 9387 application layer) from one application to another. 3.1.1.5 Connection connection Logical binding between two application objects within the same or different devices. 3.1.1.6 Cyclic redundancy check cyclicredundancycheck; CRC Value --- To detect data corruption, redundant data obtained from a block of data and stored or transmitted with the block. Method - A procedure for calculating redundant data. Note 1. The terms “CRC code”, “CRC signature”, and symbols (such as CRC1 and CRC2) are also used in this standard to indicate redundant data. Note 2. See [34] and [35]. 3.1.1.7 Error error The difference between a calculated or observed or measured value or condition and a true, prescribed or theoretically correct value or condition. [IEC 61508-4.2010], [IEC 61158] Note 1. Errors may be caused by design errors in hardware/software, and/or due to electromagnetic interference and/or other effects that result in information corruption. Note 2. Errors do not necessarily lead to failure or failure. 3.1.1.8 Failure failure The functional unit performs the termination of the ability to perform a function, or the operation of the functional unit in any non-required manner. Note 1. As defined in IEC 61508-4, there are additional notes. [IEC 61508-4.2010, modified], [GB/T 5271.14-2008, 1.11, modified] Note 2. Failure may be caused by an error (such as hardware/software design or message corruption). 3.1.1.9 Fault fault An abnormal condition that causes a functional unit to perform a required function or to lose its ability. Note. IEV191-05-01 defines “fault” as a feature state that is incapable of performing the required function, does not include preventive maintenance, or other planned actions. During the period, or the lack of external resources to produce incompetence. [IEC 61508-4.2010, modified], [GB/T 5271.14-2008, 1.10, modified] 3.1.1.10 Fieldbus fieldbus Communication systems based on serial data transmission and used in industrial automation or process control applications. 3.1.1.11 Fieldbus system fieldbussystem A system that uses a fieldbus to connect devices. 3.1.1.12 Frame frame Synonym for DLPDU. 3.1.1.13 Frame check sequence framechecksequence; FCS To detect data corruption, a hash function is used to obtain and transmit from or to the data block within the DLPDU (frame). Redundant data. Note 1. FCS can be obtained by CRC or other hash function. Note 2. See [34], [35]. 3.1.1.14 Hash function hashfunction A (mathematical) function that maps a (possibly very large) set of values to a (usually) smaller set of values. Note 1. The hash function is used to detect data corruption. Note 2. The general hash function includes a parity bit, a checksum or a CRC. [IEC /T R62210, revised] 3.1.1.15 Dangerous hazard A state or set of conditions of a system. Together with other relevant conditions, he will inevitably cause personal, property or environmental damage. hurt. 3.1.1.16 Master station master An active communication entity capable of initiating and scheduling communication activities of other stations, which may be primary or secondary. 3.1.1.17 Message message An ordered octet sequence for transmitting information. [GB/T 5271.16-2008, 2.1, modified] 3.1.1.18 Performance level performancelevel; PL Discrete level, which is used to specify the ability of a safety-related part of a control system to perform safety functions under foreseeable conditions. [GB/T 16855.1-2008] 3.1.1.19 Protection extra low voltage protectiveextra-low-voltage; PELV Under normal and single fault conditions (excluding ground faults in other circuits), the circuit voltage must not exceed AC 30Vr.ms and 42.4V peak voltage, or no more than 60V DC. Note. The PELV circuit is similar to the SELV circuit connected to the protective ground. [IEC 61131-2-2008] 3.1.1.20 Redundant redundency For functional units that perform a required function or for data representing information, there is nothing more than enough. Note. Same as the definition in IEC 61508-4, with additional examples and notes. [IEC 61508-4.2010, modified], [GB/T 5271.14-2008, 1.12, modified] 3.1.1.21 Reliability Under given conditions, for a given time interval (t1, t2), the automation system is able to perform the required function probability. Note 1. It is generally assumed that the automation system is in a state where the required function is performed at the beginning of the time interval. Note 2. This term is also used to denote the reliability performance quantified by probability. Note 3. During the MTBF or MTTF period, the possibility of the automation system performing the required function under given conditions is reduced.......Tips & Frequently Asked Questions:Question 1: How long will the true-PDF of GB/T 36006-2018_English be delivered?Answer: Upon your order, we will start to translate GB/T 36006-2018_English as soon as possible, and keep you informed of the progress. The lead time is typically 4 ~ 7 working days. 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