ImageVerifierCode 换一换
格式:PDF , 页数:198 ,大小:4.27MB ,
资源ID:574018      下载积分:10000 积分
快捷下载
登录下载
邮箱/手机:
温馨提示:
如需开发票,请勿充值!快捷下载时,用户名和密码都是您填写的邮箱或者手机号,方便查询和重复下载(系统自动生成)。
如填写123,账号就是123,密码也是123。
特别说明:
请自助下载,系统不会自动发送文件的哦; 如果您已付费,想二次下载,请登录后访问:我的下载记录
支付方式: 支付宝扫码支付 微信扫码支付   
注意:如需开发票,请勿充值!
验证码:   换一换

加入VIP,免费下载
 

温馨提示:由于个人手机设置不同,如果发现不能下载,请复制以下地址【http://www.mydoc123.com/d-574018.html】到电脑端继续下载(重复下载不扣费)。

已注册用户请登录:
账号:
密码:
验证码:   换一换
  忘记密码?
三方登录: 微信登录  

下载须知

1: 本站所有资源如无特殊说明,都需要本地电脑安装OFFICE2007和PDF阅读器。
2: 试题试卷类文档,如果标题没有明确说明有答案则都视为没有答案,请知晓。
3: 文件的所有权益归上传用户所有。
4. 未经权益所有人同意不得将文件中的内容挪作商业或盈利用途。
5. 本站仅提供交流平台,并不能对任何下载内容负责。
6. 下载文件中如有侵权或不适当内容,请与我们联系,我们立即纠正。
7. 本站不保证下载资源的准确性、安全性和完整性, 同时也不承担用户因使用这些下载资源对自己和他人造成任何形式的伤害或损失。

版权提示 | 免责声明

本文(BS EN 16603-10-04-2015 Space engineering Space environment《航天工程 航天环境》.pdf)为本站会员(ownview251)主动上传,麦多课文库仅提供信息存储空间,仅对用户上传内容的表现方式做保护处理,对上载内容本身不做任何修改或编辑。 若此文所含内容侵犯了您的版权或隐私,请立即通知麦多课文库(发送邮件至master@mydoc123.com或直接QQ联系客服),我们立即给予删除!

BS EN 16603-10-04-2015 Space engineering Space environment《航天工程 航天环境》.pdf

1、BSI Standards PublicationBS EN 16603-10-04:2015Space engineering SpaceenvironmentBS EN 16603-10-04:2015 BRITISH STANDARDNational forewordThis British Standard is the UK implementation of EN 16603-10-04:2015.It supersedes BS EN 14092:2002 which is withdrawn.BSI, as a member of CEN, is obliged to publ

2、ish EN 16603-10-04 as aBritish Standard. However, attention is drawn to the fact that duringthe development of this European Standard, the UK committee votedagainst its approval as a European Standard. The UK committee are of the opinion that parts of Clause 10 conflictwith ISO 14200:2012 which has

3、already been adopted by BSI. In partic-ular, Clause 10 requires the use of ESAs MASTER-2005 space debris andmeteoroid flux model, whereas ISO 14200:2012 does not prescribe theuse of a particular flux model but sets out a process for selecting andusing a model from several that are available.Further,

4、 MASTER-2005 is a relatively old flux model that has since beensuperseded by MASTER-2009. The UK Committee are of the opinionthat ISO 14200:2012 should be used to select a space debris/meteoroidflux model for the purpose of performing an impact risk assessment.ISO 14200:2012 can also be used in conj

5、unction with ISO 16126:2014which defines two different procedures for analysing impact risk.The UK participation in its preparation was entrusted to TechnicalCommittee ACE/68, Space systems and operations.A list of organizations represented on this committee can be obtainedon request to its secretar

6、y.This publication does not purport to include all the necessary provisionsof a contract. Users are responsible for its correct application. The British Standards Institution 2015.Published by BSI Standards Limited 2015ISBN 978 0 580 83404 2ICS 49.140Compliance with a British Standard cannot confer

7、immunity fromlegal obligations.This British Standard was published under the authority of the StandardsPolicy and Strategy Committee on 28 February 2015.Amendments/corrigenda issued since publicationDate Text affectedBS EN 16603-10-04:2015EUROPEAN STANDARDNORME EUROPENNEEUROPISCHE NORMEN 16603-10-04

8、 January 2015 ICS 49.140 Supersedes EN 14092:2002 English version Space engineering - Space environment Ing?ierie spatiale - Environnement spatial Raumfahrttechnik - Raumfahrtumweltbedingungen This European Standard was approved by CEN on 28 December 2013. CEN and CENELEC members are bound to comply

9、 with the CEN/CENELEC Internal Regulations which stipulate the conditions for giving this European Standard the status of a national standard without any alteration. Up-to-date lists and bibliographical references concerning such national standards may be obtained on application to the CEN-CENELEC M

10、anagement Centre or to any CEN and CENELEC member.This European Standard exists in three official versions (English, French, German). A version in any other language made by translation under the responsibility of a CEN and CENELEC member into its own language and notified to the CEN-CENELEC Managem

11、ent Centre has the same status as the official versions. CEN and CENELEC members are the national standards bodies and national electrotechnical committees of Austria, Belgium, Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia, Finland, Former Yugoslav Republic of Macedonia, France, German

12、y, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and United Kingdom. CEN-CENELEC Management Centre: Avenue Marnix 17, B-1000 Brussels 2015 CEN/CENELEC All rights o

13、f exploitation in any form and by any means reservedworldwide for CEN national Members and for CENELECMembers. Ref. No. EN 16603-10-04:2015 E BS EN 16603-10-04:2015EN 16603-10-04:2015 (E) 2 Table of contents Foreword 12 Introduction 13 1 Scope . 14 2 Normative references . 15 3 Terms, definitions an

14、d abbreviated terms 17 3.1 Terms defined in other standards . 17 3.2 Terms specific to the present standard . 17 3.3 Abbreviated terms. 26 4 Gravity . 29 4.1 Introduction and description 29 4.1.1 Introduction . 29 4.1.2 Gravity model formulation . 29 4.1.3 Third body gravitation 31 4.1.4 Tidal effec

15、ts. 31 4.2 Requirements for model selection and application 31 4.2.1 General requirements for gravity models . 31 4.2.2 Selection and application of gravity models . 32 5 Geomagnetic fields 33 5.1 Introduction and description 33 5.1.1 The geomagnetic field and its sources 33 5.1.2 The internal field

16、 . 33 5.1.3 External field: ionospheric components . 34 5.1.4 External magnetic field: magnetospheric components . 34 5.1.5 Models of the internal and external geomagnetic fields . 34 5.2 Requirements for model selection and application 36 5.2.1 The internal field . 36 5.2.2 The external field 36 5.

17、3 Tailoring guidelines . 37 BS EN 16603-10-04:2015EN 16603-10-04:2015 (E)BS EN 16603-10-04:2015EN 16603-10-04:2015 (E) 2 Table of contents Foreword 12 Introduction 13 1 Scope . 14 2 Normative references . 15 3 Terms, definitions and abbreviated terms 17 3.1 Terms defined in other standards . 17 3.2

18、Terms specific to the present standard . 17 3.3 Abbreviated terms. 26 4 Gravity . 29 4.1 Introduction and description 29 4.1.1 Introduction . 29 4.1.2 Gravity model formulation . 29 4.1.3 Third body gravitation 31 4.1.4 Tidal effects. 31 4.2 Requirements for model selection and application 31 4.2.1

19、General requirements for gravity models . 31 4.2.2 Selection and application of gravity models . 32 5 Geomagnetic fields 33 5.1 Introduction and description 33 5.1.1 The geomagnetic field and its sources 33 5.1.2 The internal field . 33 5.1.3 External field: ionospheric components . 34 5.1.4 Externa

20、l magnetic field: magnetospheric components . 34 5.1.5 Models of the internal and external geomagnetic fields . 34 5.2 Requirements for model selection and application 36 5.2.1 The internal field . 36 5.2.2 The external field 36 5.3 Tailoring guidelines . 37 BS EN 16603-10-04:2015EN 16603-10-04:2015

21、 (E) 3 6 Natural electromagnetic radiation and indices 38 6.1 Introduction and description 38 6.1.1 Introduction . 38 6.1.2 Electromagnetic radiation and indices . 38 6.2 Requirements . 41 6.2.1 Electromagnetic radiation 41 6.2.2 Reference index values . 42 6.2.3 Tailoring guidelines . 42 6.3 Tables

22、 . 43 7 Neutral atmospheres 45 7.1 Introduction and description 45 7.1.1 Introduction . 45 7.1.2 Structure of the Earths atmosphere 45 7.1.3 Models of the Earths atmosphere . 45 7.1.4 Wind model of the Earths homosphere and heterosphere 46 7.2 Requirements for atmosphere and wind model selection 47

23、7.2.1 Earth atmosphere . 47 7.2.2 Earth wind model 48 7.2.3 Models of the atmospheres of the planets and their satellites . 48 8 Plasmas . 49 8.1 Introduction and description 49 8.1.1 Introduction . 49 8.1.2 Ionosphere 49 8.1.3 Plasmasphere . 50 8.1.4 Outer magnetosphere . 50 8.1.5 Solar wind . 51 8

24、.1.6 Magnetosheath . 51 8.1.7 Magnetotail . 51 8.1.8 Planetary environments 52 8.1.9 Induced environments . 52 8.2 Requirements for model selection and application 52 8.2.1 General . 52 8.2.2 Ionosphere 53 8.2.3 Auroral charging environment . 53 8.2.4 Plasmasphere . 54 8.2.5 Outer magnetosphere . 54

25、 8.2.6 The solar wind (interplanetary environment) 55 BS EN 16603-10-04:2015EN 16603-10-04:2015 (E)BS EN 16603-10-04:2015EN 16603-10-04:2015 (E) 4 8.2.7 Other plasma environments 55 8.2.8 Tables . 56 9 Energetic particle radiation . 57 9.1 Introduction and description 57 9.1.1 Introduction . 57 9.1.

26、2 Overview of energetic particle radiation environment and effects 57 9.2 Requirements for energetic particle radiation environments 60 9.2.1 Trapped radiation belt fluxes . 60 9.2.2 Solar particle event models . 62 9.2.3 Cosmic ray models 63 9.2.4 Geomagnetic shielding 63 9.2.5 Neutrons . 63 9.2.6

27、Planetary radiation environments 64 9.3 Preparation of a radiation environment specification . 64 9.4 Tables . 65 10 Space debris and meteoroids 66 10.1 Introduction and description 66 10.1.1 The particulate environment in near Earth space 66 10.1.2 Space debris . 66 10.1.3 Meteoroids 67 10.2 Requir

28、ements for impact risk assessment and model selection 67 10.2.1 General requirements for meteoroids and space debris 67 10.2.2 Model selection and application 68 10.2.3 The MASTER space debris and meteoroid model . 69 10.2.4 The meteoroid model 69 10.2.5 Impact risk assessment . 70 10.2.6 Margins an

29、d worst case fluxes 71 11 Contamination 72 11.1 Introduction and description 72 11.1.1 Introduction . 72 11.1.2 Description of molecular contamination . 72 11.1.3 Transport mechanisms 73 11.1.4 Description of particulate contamination 73 11.1.5 Transport mechanisms 74 11.2 Requirements for contamina

30、tion assessment . 74 Annex A (normative) Natural electromagnetic radiation and indices . 75 BS EN 16603-10-04:2015EN 16603-10-04:2015 (E)BS EN 16603-10-04:2015EN 16603-10-04:2015 (E) 4 8.2.7 Other plasma environments 55 8.2.8 Tables . 56 9 Energetic particle radiation . 57 9.1 Introduction and descr

31、iption 57 9.1.1 Introduction . 57 9.1.2 Overview of energetic particle radiation environment and effects 57 9.2 Requirements for energetic particle radiation environments 60 9.2.1 Trapped radiation belt fluxes . 60 9.2.2 Solar particle event models . 62 9.2.3 Cosmic ray models 63 9.2.4 Geomagnetic s

32、hielding 63 9.2.5 Neutrons . 63 9.2.6 Planetary radiation environments 64 9.3 Preparation of a radiation environment specification . 64 9.4 Tables . 65 10 Space debris and meteoroids 66 10.1 Introduction and description 66 10.1.1 The particulate environment in near Earth space 66 10.1.2 Space debris

33、 . 66 10.1.3 Meteoroids 67 10.2 Requirements for impact risk assessment and model selection 67 10.2.1 General requirements for meteoroids and space debris 67 10.2.2 Model selection and application 68 10.2.3 The MASTER space debris and meteoroid model . 69 10.2.4 The meteoroid model 69 10.2.5 Impact

34、risk assessment . 70 10.2.6 Margins and worst case fluxes 71 11 Contamination 72 11.1 Introduction and description 72 11.1.1 Introduction . 72 11.1.2 Description of molecular contamination . 72 11.1.3 Transport mechanisms 73 11.1.4 Description of particulate contamination 73 11.1.5 Transport mechani

35、sms 74 11.2 Requirements for contamination assessment . 74 Annex A (normative) Natural electromagnetic radiation and indices . 75 BS EN 16603-10-04:2015EN 16603-10-04:2015 (E) 5 A.1 Solar activity values for complete solar cycle 75 A.2 Tables . 76 Annex B (normative) Energetic particle radiation 80

36、B.1 Historical dates of solar maximum and minimum 80 B.2 GEO model (IGE-2006) 80 B.3 ONERA MEOv2 model . 80 B.4 FLUMIC model . 81 B.4.1 Overview . 81 B.4.2 Outer belt (L2,5 Re) 81 B.4.3 Inner belt (L10 MeV) and electrons (10 MeV) at 400 km altitude showing the inner radiation belts “South Atlantic a

37、nomaly” and, in the case of electrons, the outer radiation belt encountered at high latitudes . 164 Figure I-4 : Comparison of POLE with AE8 (flux vs. Energy) for 15 year mission (with worst case and best case included) 165 Figure I-5 : Comparison of ONERA/GNSS model from 0,28 MeV up to 1,12 MeV (be

38、st case, mean case and worst case) with AE8 (flux vs. Energy) for 15 yr mission (with worst case E is the energy; m is the particle mass. 3.2.12 dose quantity of radiation delivered at a position NOTE In its broadest sense this can include the flux of particles, but in the context of space energetic

39、 particle radiation effects, it usually refers to the energy absorbed locally per unit mass as a result of radiation exposure. 3.2.13 dose equivalent radiation quantity normally applied to biological effects and includes scaling factors to account for the more severe effects of certain kinds of radi

40、ation 3.2.14 dust particulates which have a direct relation to a specific solar system body and which are usually found close to the surface of this body (e.g. Lunar, Martian or Cometary dust) 3.2.15 Earth infrared thermal radiation emitted by the Earth NOTE It is also called outgoing long wave radi

41、ation. 3.2.16 energetic particle particles which, in the context of space systems radiation effects, can penetrate outer surfaces of spacecraft NOTE For electrons, this is typically above 100 keV, while for protons and other ions this is above 1 MeV. Neutrons, gamma rays and X-rays are also consider

42、ed energetic particles in this context. 3.2.17 equivalent fluence quantity which attempts to represent the damage at different energies and from different species NOTE 1 For example: For solar cell degradation it is often taken that one 10 MeV protons is “equivalent” to 3 000 electrons of 1 MeV. Thi

43、s concept also occurs in consideration of Non-ionizing Energy Loss effects (NIEL). NOTE 2 Damage coefficients are used to scale the effect caused by particles to the damage caused by a standard particle and energy. BS EN 16603-10-04:2015EN 16603-10-04:2015 (E)BS EN 16603-10-04:2015EN 16603-10-04:201

44、5 (E) 20 3.2.18 exosphere part of the Earths atmosphere above the thermosphere for which the mean free path exceeds the scale height, and within which there are very few collisions between atoms and molecules NOTE 1 Near the base of the exosphere atomic oxygen is normally the dominant constituent. N

45、OTE 2 With increasing altitude, the proportion of atomic hydrogen increases, and hydrogen normally becomes the dominant constituent above about 1 000 km. Under rather special conditions (i.e. winter polar region) He atoms can become the major constituent over a limited altitude range. NOTE 3 A small

46、 fraction of H and He atoms can attain escape velocities within the exosphere. 3.2.19 external field part of the measured geomagnetic field produced by sources external to the solid Earth NOTE the external sources are mainly: electrical currents in the ionosphere, the magnetosphere and coupling curr

47、ents between these regions. 3.2.20 F10.7 flux solar flux at a wavelength of 10.7 cm in units of 104Jansky (one Jansky equals 10-26 Wm-2Hz-1) 3.2.21 fluence time-integration of the flux 3.2.22 flux amount of radiation crossing a surface per unit of time, often expressed in “integral form” as particle

48、s per unit area per unit time (e.g. electrons cm-2s-1) above a certain threshold energy NOTE The directional flux is the differential with respect to solid angle (e.g. particles cm-2steradian-1s-1) while the “differential” flux is differential with respect to energy (e.g. particles cm-2MeV-1s-1). In

49、 some cases fluxes are also treated as a differential with respect to Linear Energy Transfer (see 3.2.32). 3.2.23 free molecular flow regime condition where the mean free path of a molecule is greater than the dimensions of the volume of interest (characteristic length) 3.2.24 geocentric solar magnetospheric coordinates (GSM) elements of a right-handed Cartesian coordinate system (X,Y,Z) with the origin at the centre of the Earth BS EN 16603-10-04:2015EN 16603-10-04:2015 (E)BS EN 16603-10-04:2015EN 16603-10-04:2015 (E) 20 3.2.18 exosphere part of the Earths atmosphere above t

copyright@ 2008-2019 麦多课文库(www.mydoc123.com)网站版权所有
备案/许可证编号:苏ICP备17064731号-1