BS EN IEC 62714-5:2022 Engineering Data Exchange Format for Use in Industrial Automation Systems Engineering

Automation Markup Language Communication

Standard Number: BS EN IEC 62714-5:2022

Pages: 68

Released: 2022-05-13

ISBN: 978 0 539 12274 9

Status: Standard

Overview

The BS EN IEC 62714-5:2022 standard is a comprehensive guide designed to facilitate the exchange of engineering data in industrial automation systems. This standard focuses on the use of Automation Markup Language (AML) for communication, ensuring seamless integration and interoperability between various systems and components within an industrial setup.

Key Features

• Standardized Communication: Ensures consistent and reliable data exchange across different platforms and systems.
• Automation Markup Language (AML): Utilizes AML to provide a robust framework for data representation and communication.
• Comprehensive Coverage: Spanning 68 pages, this standard covers all essential aspects of engineering data exchange.
• Up-to-Date Information: Released on May 13, 2022, it includes the latest advancements and best practices in the field.
• Global Recognition: Recognized and adopted internationally, ensuring compatibility and compliance across borders.

Benefits

Implementing the BS EN IEC 62714-5:2022 standard in your industrial automation systems offers numerous benefits:

• Enhanced Interoperability: Facilitates seamless communication between different systems, reducing integration complexities.
• Improved Efficiency: Streamlines data exchange processes, leading to faster and more efficient operations.
• Reduced Errors: Minimizes the risk of data misinterpretation and errors, ensuring accurate and reliable information flow.
• Future-Proofing: Adopting a standardized approach prepares your systems for future technological advancements and integrations.
• Cost Savings: Reduces the need for custom solutions and extensive rework, leading to significant cost savings in the long run.

Applications

The BS EN IEC 62714-5:2022 standard is applicable across a wide range of industries and scenarios, including:

• Manufacturing: Enhances communication between various manufacturing systems and equipment.
• Process Automation: Facilitates data exchange in complex process automation setups.
• Energy Sector: Ensures reliable data communication in energy production and distribution systems.
• Transportation: Supports the integration of automation systems in transportation and logistics.
• Building Automation: Streamlines data exchange in smart building and infrastructure projects.

Technical Specifications

The BS EN IEC 62714-5:2022 standard provides detailed technical specifications to ensure effective implementation:

• Data Representation: Defines the structure and format for representing engineering data using AML.
• Communication Protocols: Specifies the protocols and methods for data exchange between systems.
• Integration Guidelines: Offers guidelines for integrating AML-based communication into existing systems.
• Compliance Requirements: Outlines the requirements for compliance with the standard.
• Best Practices: Includes best practices and recommendations for optimal implementation.

Why Choose BS EN IEC 62714-5:2022?

Choosing the BS EN IEC 62714-5:2022 standard for your industrial automation systems engineering needs ensures that you are adopting a globally recognized and reliable framework for data exchange. This standard not only enhances the efficiency and reliability of your systems but also prepares them for future advancements and integrations.

With its comprehensive coverage, up-to-date information, and focus on Automation Markup Language communication, the BS EN IEC 62714-5:2022 standard is an essential resource for any organization looking to optimize their industrial automation processes.

Conclusion

In today's fast-paced industrial environment, efficient and reliable data exchange is crucial for maintaining competitive advantage. The BS EN IEC 62714-5:2022 standard provides a robust and standardized framework for engineering data exchange, ensuring seamless communication and integration across various systems and platforms.

By adopting this standard, you can enhance the interoperability, efficiency, and accuracy of your industrial automation systems, leading to significant operational improvements and cost savings. Embrace the future of industrial automation with the BS EN IEC 62714-5:2022 standard and stay ahead in the ever-evolving technological landscape.

BS EN IEC 62714-5:2022

This standard BS EN IEC 62714-5:2022 Engineering data exchange format for use in industrial automation systems engineering. Automation markup language is classified in these ICS categories:

• 25.040 Industrial automation systems
• 25.040.01 Industrial automation systems in general
• 35.240.30 IT applications in information, documentation and publishing
• 01.040.01 Generalities. Terminology. Standardization. Documentation (Vocabularies)

Engineering processes of technical systems and their embedded automation systems have to be executed with increasing efficiency and quality. Especially since the project duration tends to increase as the complexity of the engineered system increases. To solve this problem, the engineering process is more often being executed by exploiting software based engineering tools exchanging engineering information and artefacts along the engineering process related tool chain. Communication systems establish an important part of modern technical systems and, especially, of automation systems embedded within them. Following the increasing decentralisation of automation systems and the application of fieldbus and Ethernet technology connecting automation devices and further interacting entities have to fulfil special requirements on communication quality, safety and security. Thus, within the engineering process of modern technical systems, engineering information and artefacts relating to communication systems also have to be exchanged along the engineering process tool chain. In each phase of the engineering process of technical systems, communication system related information can be created which can be consumed in later engineering phases. A typical application case is the creation of configuration information for communication components of automation devices including communication addresses and communication package structuring within controller programming devices during the control programming phase and its use in a device configuration tool. Another typical application case is the transmission of communication device configurations to virtual commissioning tools, to documentation tools, or to diagnosis tools. At present, the consistent and lossless transfer of communication system engineering information along the complete engineering chain of technical systems is unsolved. While user organisations and companies have provided data exchange formats for parts of the relevant information like FDCML, EDDL, and GSD the above named application cases cannot be covered by a data exchange format. Notably the networking related information describing communication relations and their properties and qualities cannot be modelled by a data exchange format.