BS EN IEC 62714-4:2020
Engineering data exchange format for use in industrial automation systems engineering. Automation markup language Logic
| Standard number: | BS EN IEC 62714-4:2020 |
| Pages: | 116 |
| Released: | 2020-12-17 |
| ISBN: | 978 0 539 16269 1 |
| Status: | Standard |
BS EN IEC 62714-4:2020 - Engineering Data Exchange Format for Industrial Automation Systems
Welcome to the future of industrial automation systems engineering with the BS EN IEC 62714-4:2020 standard. This comprehensive document is a must-have for professionals in the field of industrial automation, providing a robust framework for the exchange of engineering data using the Automation Markup Language (AML).
Overview
The BS EN IEC 62714-4:2020 standard is a pivotal resource for engineers and developers working in the realm of industrial automation. Released on December 17, 2020, this standard is part of a series that defines the Automation Markup Language (AML), a powerful tool designed to facilitate seamless data exchange across various engineering systems. With 116 pages of detailed guidelines and specifications, this document is essential for ensuring interoperability and efficiency in automation projects.
Key Features
- Standard Number: BS EN IEC 62714-4:2020
- Pages: 116
- Release Date: December 17, 2020
- ISBN: 978 0 539 16269 1
- Status: Standard
Why Choose BS EN IEC 62714-4:2020?
In the fast-evolving world of industrial automation, the ability to efficiently exchange engineering data is crucial. The BS EN IEC 62714-4:2020 standard provides a structured approach to data exchange, ensuring that all stakeholders in a project can communicate effectively and work towards common goals. Here are some reasons why this standard is indispensable:
1. Enhanced Interoperability
The standard ensures that different systems and components can work together seamlessly, reducing the risk of errors and miscommunications. By adhering to a common language, engineers can integrate various technologies and platforms with ease.
2. Improved Efficiency
With a clear framework for data exchange, projects can be completed more quickly and with fewer resources. The standard helps streamline processes, allowing teams to focus on innovation and problem-solving rather than data management.
3. Future-Proofing
As technology continues to advance, having a standardized approach to data exchange ensures that your systems remain compatible with new developments. The BS EN IEC 62714-4:2020 standard is designed to be adaptable, making it a long-term investment for your engineering projects.
Applications
The BS EN IEC 62714-4:2020 standard is applicable across a wide range of industries and sectors, including:
- Manufacturing
- Automotive
- Energy and Utilities
- Pharmaceuticals
- Food and Beverage
Any industry that relies on complex automation systems can benefit from the guidelines and specifications outlined in this standard.
Conclusion
The BS EN IEC 62714-4:2020 standard is an essential tool for any professional involved in industrial automation systems engineering. By providing a clear and comprehensive framework for data exchange, it helps ensure that projects are completed efficiently, accurately, and with a high degree of interoperability. Whether you're working on a small-scale project or a large industrial operation, this standard will help you achieve your goals and stay ahead of the competition.
Invest in the future of your engineering projects with the BS EN IEC 62714-4:2020 standard and experience the benefits of streamlined data exchange and enhanced collaboration.
BS EN IEC 62714-4:2020
This standard BS EN IEC 62714-4:2020 Engineering data exchange format for use in industrial automation systems engineering. Automation markup language is classified in these ICS categories:
- 25.040.40 Industrial process measurement and control
This part of IEC 62714 specifies the integration of logic information as part of an AML model for the data exchange in a heterogenous engineering tool landscape of production systems.
This document specifies three types of logic information: sequencing, behaviour, and interlocking information.
This document deals with the six following sequencing and behaviour logic models (covering the different phases of the engineering process of production systems) and how they are integrated in AML: Gantt chart, activity-on-node network, timing diagram, Sequential Function Chart (SFC), Function Block Diagram (FBD), and mathematical expression.
This document specifies how to model Gantt chart, activity-on-node network, and timing diagram and how they are stored in Intermediate Modelling Layer (IML).
NOTE 1 With this, it is possible to transform one logic model into another one. A forward transformation supports the information enrichment process and reduces or avoids a re-entry of information between the exchanging engineering tools.
NOTE 2 Mapping of other logic models, e.g. event-driven logic models like state charts, onto IML is possible.
This document specifies how interlocking information is modelled (as interlocking source and target groups) in AML. The interlocking logic model is stored in Function Block Diagram (FBD).
This document specifies the AML logic XML schema that stores the logic models by using IEC 61131-10.
This document specifies how to reference PLC programs stored in PLCopen XML documents.
This document does not define details of the data exchange procedure or implementation requirements for the import/export tools.