Importantl international standards for space engineering
Useful international standards for space engineering
The space industry is one of the most promising sectors of the world economy, especially given all the potential for international cooperation. At the same time, you need to understand that the competition in this industry is very high, as a rule, success here can only be achieved if you produce high-quality space equipment that meets international standards. Another distinguishing feature of this segment is the constant invention of new technologies that are important to immediately apply in their work. The competitiveness of spacecraft companies is directly proportional to the speed with which they respond to updates. One of the options that we can advise you if you are interested in being a leader in your market, as well as increasing the profitability of your company, is to focus your work on international standards, as they are constantly updated taking into account current changes in market. The norms, which are described in international standards, regulate the necessary studies and the methodology of checks, both of the components of space systems and of finished ships. This information will be useful to those companies that want to understand the needs of the market and maintain a leading position. We have collected some of these standards for you in this article so that you can familiarize yourself with them in advance.
Space engineering - Electromagnetic compatibility handbook
CEN/TR 17603-20-07:2022
The development of space engineering is accompanied by an increase in the variety of choice of components of space systems. In connection with this fact, it is worth paying attention to the fact that when developing new spacecraft, it is important to take into account all options for their compatibility. One of these indicators is electromagnetic compatibility, in order to correctly assess it, an international standard was created CEN/TR 17603-20-07:2022.
The objective of this EMC Handbook is to point out all the issues relevant to space systems EMC, to provide a general technical treatment and to address the interested reader to more thorough and in-depth publications.
NOTE: It is possible to find fundamental and advanced treatment of many aspects related to EMC: many universities offer courses on EMC and a large number of textbooks, papers and technical documents are available. Therefore replicating in this Handbook the available knowledge is impractical and meaningless. Emphasis is given to space systems EMC design, development and verification, and specifically to the practical aspects related to these issues.
NOTE: This has been possible thanks to the collaboration of space industry, especially on items which are not textbook issues and whose solution needs the widespread experience gained in large number of projects.
Companies that work in the field of space production have a lot of research that they have to do at the design stage of the ship. This International Standard is an assistant in the field of electromagnetic compatibility of space systems. If you are interested in this document, you can read the full text on our website.
Space engineering - Structural materials handbook - Part 8: Glossary
CEN/TR 17603-32-08:2022
One of the main keys to the successful implementation of spacecraft design projects is the correct theoretical training of specialists, as well as their full knowledge of the basic terms that are used in the industry. In order to simplify this process for companies, international standards are created, which are a kind of dictionaries of technical terms, one of them is CEN/TR 17603-32-08:2022.
The structural materials handbook, SMH, combines materials and design information on established polymer matrix composites with provisional information on the emerging groups of newer advanced materials and their composites. Design aspects are described, along with factors associated with joining and manufacturing. Where possible, these are illustrated by examples or case studies. The Structural materials handbook contains 8 Parts. A glossary of terms, definitions and abbreviated terms for these handbooks is contained in Part 8.
The parts are as follows: Part 1 Overview and material properties and applications Clauses 1 ‐ 9
Part 2 Design calculation methods and general design aspects Clauses 10 ‐ 22
Part 3 Load transfer and design of joints and design of structures Clauses 23 ‐ 32
Part 4 Integrity control, verification guidelines and manufacturing Clauses 33 ‐ 45
Part 5 New advanced materials, advanced metallic materials, general design aspects and load transfer and design of joints Clauses 46 ‐ 63
Part 6 Fracture and material modelling, case studies and design and integrity control and inspection Clauses 64 ‐ 81
Part 7 Thermal and environmental integrity, manufacturing aspects, in‐orbit and health monitoring, soft materials, hybrid materials and nanotechnoligies Clauses 82 ‐ 107
Part 8 Glossary NOTE: The 8 parts will be numbered TR17603-32-01 to TR 17603-32-08
The International Standard described above is an excellent guide for spacecraft companies as it helps to understand the meaning of the basic terms that are used in the industry. If this information is useful for your company, then you can purchase this standard on our website.
Space engineering - Structural materials handbook - Part 5: New advanced materials, advanced metallic materials, general design aspects and load transfer and design of joints
CEN/TR 17603-32-05:2022
The theoretical basis of space engineering contains a lot of concepts that need to be understood. Many complex technical terms can, at first glance, cause certain difficulties. To avoid this, new International Standards are regularly created and existing ones updated. One such document that describes improvements in this area is CEN/TR 17603-32-05:2022.
The structural materials handbook, SMH, combines materials and design information on established polymer matrix composites with provisional information on the emerging groups of newer advanced materials and their composites. Design aspects are described, along with factors associated with joining and manufacturing. Where possible, these are illustrated by examples or case studies. The Structural materials handbook contains 8 Parts.
A glossary of terms, definitions and abbreviated terms for these handbooks is contained in Part 8.
The parts are as follows:
Part 1 Overview and material properties and applications
Clauses 1 ‐ 9
Part 2 Design calculation methods and general design aspects
Clauses 10 ‐ 22
Part 3 Load transfer and design of joints and design of structures
Clauses 23 ‐ 32
Part 4 Integrity control, verification guidelines and manufacturing
Clauses 33 ‐ 45
Part 5 New advanced materials, advanced metallic materials, general design aspects and load transfer and design of joints
Clauses 46 ‐ 63
Part 6 Fracture and material modelling, case studies and design and integrity control and inspection
Clauses 64 ‐ 81
Part 7 Thermal and environmental integrity, manufacturing aspects, in‐orbit and health monitoring, soft materials, hybrid materials and nanotechnoligies
Clauses 82 ‐ 107
Part 8 Glossary NOTE: The 8 parts will be numbered TR17603-32-01 to TR 17603-32-08
This guide, which we talked about above, is a guide for specialists who want to understand the issues of structural materials for the construction of spacecraft. Taking into account the fact that at the moment there are many similar international standards, each of which has its own characteristics, you can seek advice from our specialists to help you choose the right one for you.
Space engineering - Structural materials handbook - Part 6: Fracture and material modelling, case studies and design and integrity control and inspection
CEN/TR 17603-32-06:2022
Space technology and all its component parts need to be tested before it is put into operation. However, even before the moment of use, all construction materials must be subjected to rigorous testing. One of the documents that describes in detail all stages of the selection of structural materials is this international standard, such as CEN/TR 17603-32-06:2022.
The structural materials handbook, SMH, combines materials and design information on established polymer matrix composites with provisional information on the emerging groups of newer advanced materials and their composites. Design aspects are described, along with factors associated with joining and manufacturing. Where possible, these are illustrated by examples or case studies. The Structural materials handbook contains 8 Parts. A glossary of terms, definitions and abbreviated terms for these handbooks is contained in Part 8. The parts are as follows:
Part 1 Overview and material properties and applications
Clauses 1 ‐ 9
Part 2 Design calculation methods and general design aspects
Clauses 10 ‐ 22
Part 3 Load transfer and design of joints and design of structures
Clauses 23 ‐ 32
Part 4 Integrity control, verification guidelines and manufacturing
Clauses 33 ‐ 45
Part 5 New advanced materials, advanced metallic materials, general design aspects and load transfer and design of joints
Clauses 46 ‐ 63
Part 6 Fracture and material modelling, case studies and design and integrity control and inspection
Clauses 64 ‐ 81
Part 7 Thermal and environmental integrity, manufacturing aspects, in‐orbit and health monitoring, soft materials, hybrid materials and nanotechnoligies
Clauses 82 ‐ 107
Part 8 Glossary
NOTE: The 8 parts will be numbered TR17603-32-01 to TR 17603-32-08
At the moment, there are many international standards that, in the form of a guide, help companies better understand all the intricacies of working in the field of space engineering. However, we also understand that sometimes difficulties may arise due to which document you need. Our experts are ready to help you in this matter, you can ask your question on our website.
Knowledge of the theoretical base as the basis for high profits in space engineering
The design of spacecraft is a very complex process that requires thorough preparation, including theoretical. In order to competently establish production processes, it is necessary to fully master the terminology that will be used here. This knowledge gives companies that are engaged in the production of space technology the opportunity to operate with terms, as well as delve deeper into all the nuances that exist in the industry. It is not surprising that in this direction, at the moment, many international standards have already been created, some of which have been developed in the format of a guidebook, which in turn simplifies the process of finding the necessary information. However, it is worth noting the fact that international standards are constantly updated and new ones are created in order to meet the needs of the end user. Particular attention in these standards is paid to the structural systems that are part of the spacecraft, and also describes the rules for testing them for suitability and endurance, since the safety of the crew that will operate it depends on these parameters. This is one of the main reasons why we talk a lot about the importance of using international standards in their work for companies that manufacture spacecraft. Summing up all of the above, we can say that if you are interested in this, so that your product is competitive and the company's profits grow, then you can seek advice from our specialists who will help you select the appropriate international standards.
References:
https://standards.iteh.ai/catalog/standards/sist/71d3b628-748a-472a-8553-d1571e49f828/sist-tp-cen-tr-17603-20-07-2022 https://standards.iteh.ai/catalog/standards/sist/643d8318-43ce-4def-b724-fbb5fec469f8/sist-tp-cen-tr-17603-32-08-2022 https://standards.iteh.ai/catalog/standards/sist/971a669c-b063-4e34-9dcf-f4c137825305/sist-tp-cen-tr-17603-32-05-2022 https://standards.iteh.ai/catalog/standards/sist/dfc3720c-79dc-4ae2-87e9-f6bd957b0f0e/sist-tp-cen-tr-17603-32-06-2022
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