INTERNATIONAL STANDARD ISO 007-2 Third edition 01 5-1 -1 Gas cylinders — Identification and marking using radio frequency identification technology — Part : Numbering schemes for radio frequency identification Bouteilles gaz — Identification et marquage l’aide de la technologie d’identification par radiofréquences — Partie 2: Schémas de numérotage pour identification par radiofréquences Reference number ISO 007-2 : 01 (E) I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n © ISO 01 ISO 1007-2 :2 015(E) COPYRIGHT PROTECTED DOCUMENT © ISO 2015, Published in Switzerland All rights reserved Unless otherwise speci fied, no part of this publication may be reproduced or utilized otherwise in any form or by any means, electronic or mechanical, including photocopying, or posting on the internet or an intranet, without prior written permission Permission can be requested from either ISO at the address below or ISO’s member body in the country of the requester ISO copyright office Ch de Blandonnet • CP 401 CH-1214 Vernier, Geneva, Switzerland Tel +41 22 749 01 11 Fax +41 22 749 09 47 copyright@iso.org www.iso.org ii I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n © ISO 2015 – All rights reserved ISO 1007-2 :2 015(E) Contents Page Foreword v Introduction vi Scope Normative references Terms, de finitions and numerical notations 3.1 Terms and de finitions Data presentation 4.1 General requirements 4.2 ASN.1 messages 4.4 Predetermined context and the use of packed encoding rules 4.5 Sample GC data structure constructs 4.3 Numerical notations Message identi fication requirements Gas cylinder identi fication structure (variable) General requirements Data structure construct 5 General 5 Length 5.2.2 5.2.4 Data scheme identi fier (DSI) Data field Gas cylinder identi fication data schemes (variable) 6.1 6.2 General requirements Data scheme “01”: numbering (binary) 6.2 General 6.2 Unique number 6.2 Conclusion 6.2.2 6.2.3 6.2.4 6.3 Data scheme “02 ”: numbering (ASCII) 6.3 General 6.3 Unique string 6.3 Conclusion 6.4.1 Overview 6.4.2 General 6.4.3 Manufacturer code 6.4.4 Manufacturer serial number 6.5.1 General 6.6.1 General 6.6.3 Working pressure (bar) 1 6.6.4 Test pressure (bar) 1 6.6.5 Tare weight (kg) 6.6.6 Last test date 6.3.2 6.3.3 6.3.4 6.4 6.5 6.6 Issuer country code Registration body Issuer identi fier Data scheme “10”: cylinder manufacturer information (optional) Data scheme “11”: cylinder approval information (optional) 6.5.2 Country code Data scheme “12”: cylinder package information (optional) 6.6.2 6.7 Issuer country code Registration body Issuer identi fier Water capacity (l) 1 Data scheme “13”: cylinder content information (optional) © ISO 01 – All rights reserved I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n iii ISO 1007-2 :2 015(E) 6.8 6.7.1 General 6.7.2 Content code 6.7.3 Fill date Data scheme “1 4”: commercial product information (optional) 6.8.1 General 6.8.4 Product ID 6.8.2 6.8.3 6.9 6.1 6.11 Data scheme “1 ”: production lot information (optional) 6.9.1 General 6.9.2 Expiration date 6.9.3 Lot ID Data scheme “1 6”: accessories information (optional) Data scheme “20”: acetylene speci fics (optional) 6.1 1 General 6.1 Porous mass characteristics Gas cylinder identi fication structure (optimized storage size) 15 7.1 General 7.2 Data structure construct 7.2 General 7.2 Data item attribute 7.2.2 7.2 Quantity Quantity unit code DSI (fix) Remarks Air interface specifications 16 8.1 Technical requirements 8.2 Downlink and uplink 8.3 Standard downlink/uplink parameters Transponder memory addressing 17 9.1 General requirements 9.2 Modbus/JBUS implementation Technical solution 19 Annex B (informative) List of codes for registration bodies Annex C (informative) Gas quantity units code Annex D (informative) Host to interrogator to Modbus communication protocol 2 Annex E (informative) Data scheme identi fier (DSI) de finition for fixed length format Bibliography 41 Annex A (normative) iv I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n © ISO 01 – All rights reserved ISO 1007-2 :2 015(E) Foreword ISO (the International Organization for Standardization) is a worldwide federation of national standards bodies (ISO member bodies) The work of preparing International Standards is normally carried out through ISO technical committees Each member body interested in a subject for which a technical committee has been established has the right to be represented on that committee International organizations, governmental and non-governmental, in liaison with ISO, also take part in the work ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of electrotechnical standardization The procedures used to develop this document and those intended for its further maintenance are described in the ISO/IEC Directives, Part In particular the different approval criteria needed for the different types of ISO documents should be noted This document was drafted in accordance with the editorial rules of the ISO/IEC Directives, Part (see www.iso.org/directives) Attention is drawn to the possibility that some of the elements of this document may be the subject of patent rights ISO shall not be held responsible for identifying any or all such patent rights Details of any patent rights identi fied during the development of the document will be in the Introduction and/or on the ISO list of patent declarations received (see www.iso.org/patents) Any trade name used in this document is information given for the convenience of users and does not constitute an endorsement For an explanation on the meaning of ISO speci fic terms and expressions related to conformity assessment, as well as information about ISO’s adherence to the WTO principles in the Technical Barriers to Trade (TBT) see the following URL: Foreword - Supplementary information The committee responsible for this document is ISO/TC 58, Operational requirements for gas cylinders Gas cylinders, Subcommittee SC 4, This third edition cancels and replaces the second edition (ISO 21007-2: 2013) , which has been technically revised with the following changes: — a new registration body has been added to Annex B; — a new Annex E has been added; — the former Annex C, which provided a list of RFID codes, as well as marks for gas cylinder manufacturers, has been removed from this part of ISO 210 07 and will be published in a separate document, ISO/TR 1732 ISO 21007 consists of the following parts, under the general title marking using radio frequency identification technology: — Part 1: Reference architecture and terminology — Part 2: Numbering schemes for radio frequency identification © ISO 01 – All rights reserved I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n Gas cylinders — Identification and v ISO 1007-2 :2 015(E) Introduction Cylinders can contain a wide variety of gases, and identi fication is of paramount importance It could be desirable to identify not only the type of gas or liquid contained in the GC, but also such details as the filling station where the cylinder was filled, the batch of cylinders filled and the date the cylinder was filled Various methods and technologies such as physical identi fication through indentation; paper, card, metal and plastic labelling; colour code identi fication; bar coding and, in some circumstances, vision systems are already used to make or assist such identi fications The technology of radio frequency identi fication (RFID) involves a reader/interrogator station that transmits a predetermined signal of inductive, radio or microwave energy to one or many transponders located within a read zone The transponder returns the signal in a modi fied form to the reader/interrogator and the data are decoded The data component in a portable gas or liquid cylinder environment provides the basis for unambiguous identi fication of the transponder and also can p ro vi de a me d i u m fo r a b i- d i re c tio n a l i n te rac ti ve e xch a n ge o f d ata b e t we e n the re ade r/i n te r ro gato r and transponder The signal can be modulated or unmodulated according to architecture of the system Recently, RFID has started using new, higher frequencies called ultra high frequency (UHF) These h i ghe r fre que nc i e s fac i l i t ate a fa s te r re ad i n g a nd w r i ti n g p ro c e s s a nd de l i ve r lo n ge r re ad i n g/w r i ti n g distances Therefore, the UHF band frequency has been included in this part of ISO 21007 The aim of this part of ISO 21007 is to provide the data structure respectively suitable for all frequency bands i nc lud i n g U H F In many cases, it is necessary or desirable to use one air carrier frequency and protocol; however, this will not always be the case Within a global market, different applications could require different solutions for the carrier frequency (e.g reading distance and velocity) and protocols (e.g security, company rule) However, there is bene fit in using a standard common core data structure that is capable of upwards integration and expandable from the simplest low-cost cylinder identi fication system to more complex functions Such a structure will have to be flexible and enabling rather than prescriptive, thus enabling different systems degrees of interoperability within and between their host systems The use of Abstract Syntax Notation One (ASN.1, as de fined in the ISO/IEC 8824 series) from ISO/IEC 8824-1 as a notation to specify data and its associated Packed Encoding Rules (PER) from ISO/IEC 8825-2 is widely used and gaining popularity Its usage will provide maximum interoperability and conformance to existing standards and will meet the speci fically de fined requirements for a generic standard model for gas cylinder identi fication in that it — e n ab le s a nd u s e s e x i s ti n g s ta n d a rd c o d i n g , — i s ad ap t ab le a nd e x p a nd ab le , — does not include unnecessary information for a speci fic application, and — h a s a m i n i mu m o f o ve rhe ad i n s to r a ge a nd tra n s m i s s io n RFID standards other than ASN.1, for de finition of frequencies and protocols, have been developed within recent years [see ISO/IEC 18000 (all parts)] ISO 21007-1 provides a framework reference architecture for such systems This part of ISO 21007 is a supporting part to ISO 21007-1 and provides a standardized yet flexible and interoperable framework fo r nu mb e r i n g s c he me s This p ar t of ISO 10 de ta i l s i nd i v idu a l framework for the automatic identi fication of gas cylinders nu mb e r i n g s che me s w i th i n the Central to the effective use of many of the constructs is a structure to provide unambiguous identi fication This part of ISO 21007 provides a standardized data element construct for the automatic identi fication of gas cylinders vi I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n © I S O – Al l ri gh ts re s e rve d ISO 1007-2 :2 015(E) The inconvenience of such a flexible concept is that a large storage memory is needed, particularly if a large amount of information has to be stored and read directly from the RFID tag T he fo l lo w i n g t wo a l te r n ati ve s co u ld b e u s e d to add re s s th i s i s s ue : — limit the information directly accessible on the RFID tag and obtain the additional information from the host (ERP system); — use a fixed data structure and length as shown in A n ne x E , a s th i s c a n m i n i m i z e the s to r a ge de m a n d This part of ISO 21007 is intended to be used under a variety of national regulatory regimes, but has b e e n w r i t te n s o th at i t i s s u i tab le fo r the ap p l ic atio n o f the U N M o de l Re g u l ati o n s [ ] At te n ti o n i s d raw n to requirements in the relevant national regulations of the country (countries) where the cylinders are i nte n de d to b e u s e d th at m i ght o ve r r ide the re qu i re me n ts g i ve n i n th i s p a r t o f I S O 0 W he re the re is any flict between this part of ISO 21007 and any applicable regulation, the regulation always ta ke s p re ce de nc e © I S O – Al l ri gh ts re s e rve d I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n vi i I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n INTERNATIONAL STANDARD ISO 1007-2 :2 015(E) Gas cylinders — Identification and marking using radio frequency identification technology — Part : Numbering schemes for radio frequency identification Scope establishes a common f lexible framework for data structure to enable the unambiguous identi fication in gas cylinder (GC) applications and for other common data elements This part of I SO 10 07 i n t h i s s e c to r This part of ISO 21007 enables a structure to allow some harmonization between different systems However, it does not prescribe any one system and has been written in a non-mandatory style so as not to make it obsolete as technology changes The main body of this part of ISO 21007 excludes any data elements that form any part of transmission o r s to ge p ro to co l s s uc h a s he ade r s a nd che c ks u m s For details on cylinder/tag operations, see A n ne x A Normative references The following documents, in whole or in part, are normatively referenced in this document and are indispensable for its application For dated references, only the edition cited applies For undated references, the latest edition of the referenced document (including any amendments) applies I S O 16 -1 , I S O 76 , Codes for the representation ofnames ofcountries and their subdivisions — Part 1: Country codes Gas cylinders — Stamp marking Gas cylinders — Identification of gas cylinder manufacturer marks and their assigned radio frequency identification (RFID) codes I S O/ T R 17 9, Gas cylinders — Identification and marking using radio frequency identification technology — Part 1: Reference architecture and terminology ISO 0 7-1 : 0 , Information technology — Abstract Syntax Notation One (ASN.1): Specification of basic notation — Part I S O/ I E C 8 -1 : 0 , I S O/ I E C 8 -2 , (PER) Information technology — ASN.1 encoding rules: Specification of Packed Encoding Rules Information technology — Radio frequency identification for item management — Part 6: Parameters for air interface communications at 860 MHz to 960 MHz General I S O/ I E C 180 0 - 6, Terms, definitions and numerical notations 3.1 Terms and de finitions For the purposes of this document, the terms and de finitions given in © I S O – Al l ri gh ts re s e rve d I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n I S O 10 7-1 and the following apply ISO 1007-2 :2 015(E) 1.1 bit rates number of bits per second, independent of the data coding 1.2 carrier frequency centre frequency of the downlink/uplink band 1.3 construct one or more primitive constructs to form an ASN.1 message 1.4 data coding coding that determines the baseband signal presentation, i.e., a mapping of logical bits to physical signals Note to entry: Examples are bi-phase schemes (Manchester, Miller, FM0, FM1, differential Manchester) , N RZ and N RZ1 1.5 modulation keying of the carrier wave by coded data described in accordance with commonly understood methodologies (amplitude shift keying, frequency shift keying) 1.6 octet set of eight binary digits (bits) 1.7 power limits within communication zone limits that determine the minimum and maximum values of incident power referred to a dB antenna in front of the tag Note to entry: These two values also specify the dynamic range of the tag receiver Power values are measured without any additional losses due to rain or misalignment 1.8 registration body organization entitled to issue and keep track of issuer identi fication Note to entry: For examples, see Annex B 1.9 tolerance of carrier frequency maximum deviation of the carrier frequency expressed as a percentage 3.2 Numerical notations The numerical notations used in this part of ISO 21007 are as follows: — decimal (“normal” ) notation has no subscript, e.g 127; — hexadecimal numbers are noted by subscript 16, e.g 7F 16 ; — binary numbers are noted by subscript 2, e.g 01111111 I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n © ISO 01 – All rights reserved ISO 1007-2 :2 015(E) E.2.2 List of data items and memory address Table E.3 — List of data item and memory address for JIMGA format Ver.3 Item no Type Offset Bits 16 Binary Binary Binary 16 24 GC symbol ASCII 32 48 GC number ASCII 80 48 GC manufacturer code (optional) 128 17 Gas kind (optional) 145 15 GC owner’s phone number (optional) 160 32 GC expiration date (optional) 192 16 20 18 226 11 237 11 248 251 256 16 272 16 288 16 304 12 316 16 332 16 48 16 64 16 80 16 96 16 41 16 Decimal 42 12 Decimal 440 12 Decimal 452 12 464 11 475 476 480 24 50 Reserved Format ID GC class (optional) 10 GC owner code (optional) 11 Notice code/“No oil allowed,” toxicity, etc (optional) 12 Last pressure retest date of GC (optional) 13 Fill volume unit (optional) 14 Reserved 15 Tare weight (optional) 16 Fill volume (optional) 17 Fill date (optional) 18 Fill pressure (optional) 19 Expiration date of content filled (optional) 20 Fill s tation ship date (optional) 21 Return due date (optional) 22 Dealer ship date (optional) 28 GC delivery date (optional) Empty GC collection date (1) (optional) Empty GC collection date (2) (optional) Operator code fill in GC delivery date (optional) Operator code fill in empty GC collection date (1) (optional) Operator code fill in empty GC collection date (2) (optional) 29 GC manufacture date (optional) 30 GC status, filled/empty (optional) 31 GC use kind (optional) 32 Free area (optional) 33 Reserved 23 24 25 26 27 28 Item name I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n Binary Binary Decimal Binary Binary Binary Binary Binary Binary Binary Binary Binary Binary Binary Binary Binary Binary Binary Binary Binary Binary Binary Decimal Binary Binary © ISO 01 – All rights reserved ISO 1007-2 :2 015(E) E.2.3 Data item 3: GC class (optional) Classi fication of gas cylinder is a code for distinguishing a classi fication of cylinders such as seamless, welded, brazed, etc GC class Bits bit Classi fication1 Reserved Default value: 00 16 Classi fication2 (Reserved = 0, Classi fication1 = 0, Classi fication2 = 0) Table E.4 — GC class classi fication value Class Type of GC Seamless 1 More than 50 l Less than 50 l More than 50 l Welded, cryogenic and brazed Conditions 2 Less than 50 l excluding 2–3 to 2– LP gas cylinder from 50 l to 120 l LP gas cylinder below 50 l excluding 2–5 Below 25 l (excluding cylinders in service of hydrogen cyanide, am5 monia, and chlorine, manufactured after July 1955 and TP not more than MPa) FRP Other cylinders unnecessary to conduct retes ting 0 LP gas container for automobile fuel equipment fixed to vehicles FRP cylinder among oxygen cylinder used for domiciliary oxygen therapy - E.2.4 Data item 4: GC symbol Character section of unique identi fication number of cylinder: Fill in with a space (20 16 ) if characters are less than Bits (8 bit characters ASCII ) 48 Length Type Default ASCII 20 16 ì value E XAMPLE â ISO 01 – All rights reserved I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n Offset –7 8–15 16 –23 4–31 32–39 40 – 47 Value 41 16 42 16 43 16 20 16 20 16 20 16 ASCII “A” “B ” “C ” Space Space Space 29 ISO 1007-2 :2 015(E) When a unique identi fication number of cylinder is “ABC65535”, “ABC” + 20 16 × are stored E.2 Data item 5: GC number Number section of unique identi fication number of cylinder: Fill in with a space (20 16 ) if characters are less than Bits (8 bit characters ASCII ) 48 Length Type Default ASCII 2016 × value E XAMPLE Offset –7 8–15 16 –23 4–31 32–39 40 – 47 Value 616 35 16 35 16 33 16 35 16 16 ASCII “6” “5” “5” “3 ” “5” Space When a cylinder’s unique identi fication number is “ABC65535”, “65535” + 20 16 are stored Default value: 20 16 × When registering the identi fication number of high pressure gas cylinders outside of Japan, it is possible to treat data items and as one ASCII item with 12 characters E XAMPLE Item Data item Offset –7 –15 16 –23 4–31 32–39 40 – 47 –7 –15 16 –23 4–31 32–39 40 – 47 Value 5416 416 616 16 31 16 31 16 3016 59 16 16 16 16 16 ASCII “T” “6” “9 ” “1” “1” “0 ” Space Space Space Space “4” Data item “Y” When a cylinder’s individual identi fication number is “T469110Y”, “T46911” and “0Y” + 20 16 × shall be s tored E.2.6 Data item 6: GC manufacturer code (optional) Code of gas cylinder manufacturer: (binary 0–131 071) Bits Variables Type Default value 17 131 072 Binary To allow this, small binary structure codes for different manufacturers had to be developed (see Annex C ) In addition, although ISO has established the GC manufacturer code as 16 bits, it is extended to 17 bits for the GC manufacturer code as the code according to the country is included 16 14 13 11 10 Manufacturer of cylinder In Japan, it is possible to use the cylinder manufacturer code issued by JIMGA so that the manufacturer code for cylinders other than high pressure gas cylinders (LGC vessel, dewar, bucket, etc.) can be registered 30 I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n © ISO 01 – All rights reserved ISO 1007-2 :2 015(E) E.2.7 Data item 7: Gas kind (optional) Use the UN number or gas code which is uniquely assigned by JIMGA: UN code or code given by JIMGA Gas kind Flag bit Bits 14 bit 15 bit 14 x(0 –1) 13 12 11 10 y(0–16383) Default value: x = 0, y = x: = UN number = Gas kind code which is uniquely assigned y: UN number or gas kind code which is uniquely assigned by JIMGA E.2.8 Data item 8: GC owner’s phone number (optional) Phone number of gas cylinder owner: The telephone number is considered as one numerical value In order to store the value, the zero (“0 ” ) at the beginning is not registered (binary 0–4294967295) E XAMPLE Bits Type Default value 32 Decimal When the owner’s telephone number is “03 -1 23 4-5678 ”, it is regis tered as 31 23 45 678 10 E.2.9 Data item 9: GC expiration date (optional) Expiration date of gas cylinder: GC expiration date Bits 16 bit 15 14 13 12 11 10 Year (0 –1 27 ) Month (0 –1 ) Day (0–31) Default value: Year = 0, Month = 1, Day = Year: to 9 is effective range It is interpreted that or more is in the 19 0 s and less than is in the 0 s Month: to 12 is effective range Day: to 31 is effective range E XAMPLE 0 Year = 1 1 Month = 0 1 Day = 13 Date = 13 April 2015 © ISO 01 – All rights reserved I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n 31 ISO 1007-2 :2 015(E) E.2.10 Data item 10: GC owner code (optional) Code of gas cylinder owner: Use four-digit code de fined by KHK (The High Pressure Gas Safety Ins titute of Japan) GC owner code Bits ASCII Binary bit 10 bit 18 bit 17 16 15 14 13 12 11 10 x = Byte ASCII 0 0 0 y = (0–1023) Default value: x = “A”, y = x: Alphabet character y: Numerical value from to 999 E XAMPLE 0 1 0 0 0 y = 01 16 x = 4C 16 O wner code = L001 E.2.11 Data item 11: Notice code/“No oil allowed”, toxicity, etc (optional) Code of Notice/“No oil allowed”, toxicity, etc.: Notice information code is the guideline number shown in “Emergency measure guideline” edited by Japan Chemical Industry Association It is handled as notice information code by combining notice information and “No oil allowed”/toxicity information as “No oil allowed”/toxicity information is also included In the case when there is no applicable item in the guide number of “Emergency measure guideline”, it is also possible to use a guide number uniquely de fined by the registration body Notice code/“No oil allowed”, toxicity, Flag Guide number or the guide number uniquely de fined bit 10 bit etc Bits 11 bit 10 x(0 –1) y = (0–1 023) Default value: x = 0, y = x: = Guide number of Japan Chemical Industry Association; = Guide number uniquely de fined y: Guide number of Japan Chemical Industry Association or guide number uniquely de fined by registration body 32 I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n © ISO 01 – All rights reserved ISO 1007-2 :2 015(E) E.2.12 Data item 12: Last pressure retest date of GC (optional) Date of pressure retest of gas cylinder: Last pressure retest date of GC Bits 16 bit 15 14 13 12 11 10 Year (0 –1 27 ) Month (0 –1 ) Day (0–31) Default value: Year = 0, Month = 1, Day = Year: to 9 is effective range It is interpreted that or more is in the 19 0 s and less than is in the 0 s Month: to 12 is effective range Day: to 31 is effective range E XAMPLE 0 1 1 Year = 10 0 1 Day = 13 Month = Date = 13 April 2010 E.2.13 Data item 13: Fill volume unit (optional) Filling volume unit: Code of volume unit is numerical field indicating engineering unit used by previous volume (see Annex C ) (binary 0–7) Bits Variables Type Binary Default value: Codes and are not used in Japan E.2.14 Data item 15: Tare weight (optional) Tare weight (kg) : Tare weight Bits 15 14 13 12 11 10 x (0 –16 83) Value Multiplier 14 bit bit 16 bit y (0–3) Default value: x = 0, y = x: Valid number of digits including those digits to the right of the decimal point y: Speci fies multiplier of 10 Tare weight = x × 0,001 × 10 y © ISO 01 – All rights reserved I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n 33 ISO 1007-2 :2 015(E) E XAMPLE 0 0 1 0 1 y=2 x = 35 235 × 0,001 × 10 = 123 ,5 kg E.2.15 Data item 16: Fill volume (optional) Filling volume: Unit is indicated by fill volume unit (data item 13) Fill volume Bits Value Multiplier 14 bit bit 16 bit 15 14 13 12 11 10 y (0–3) x (0 –16 83) Default value: x = 0, y = x: Valid number of digits including those digits to the right of the decimal point y: Speci fies multiplier of 10 Fill volume = x × 0,0 01 × 10 y E XAMPLE 0 0 1 0 1 y= x = 235 235 × 0,001 × 10 = 123 ,5 E.2.16 Data item 17: Fill date (optional) Date of filling: Fill date Bits 16 bit 15 14 13 12 11 10 Year (0 –1 27 ) Month (0 –15 ) Day (0–31) Default value: Year = 0, Month = 1, Day = Year: to 9 is effective range It is interpreted that or more is in the 19 0 s and less than is in the 0 s Month: to 12 is effective range Day: to 31 is effective range E XAMPLE 1 Year = 9 34 I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n 0 1 Month = 0 1 Day = 13 © ISO 01 – All rights reserved ISO 1007-2 :2 015(E) Date = 13 April 1999 E.2.17 Data item 18: Fill pressure (optional) Filling pressure (Mp) : Fill pressure Bits 11 Value Multiplier 10 bit bit bit 10 y (0–3) x (0 –1 023) Default value: x = 0, y = x: Valid number of digits including those digits to the right of the decimal point y: Speci fies multiplier of 10 Fill pressure = x × 0,01 × 10 y E XAMPLE 0 1 1 1 y=1 x = 123 123 × 0,01 × 10 = 12 , Mp E.2.18 Data item 19: Expiration date of content filled (optional) Expiration date of content filled: Expiration date of content filled Bits 16 bit 15 14 13 12 11 10 Year (0 –1 27 ) Month (0 –15 ) Day (0–31) Default value: Year = 0, Month = 1, Day = Year: to 9 is effective range It is interpreted that or more is in the 19 0 s and less than is in the 0 s Month: to 12 is effective range Day: to 31 is effective range E XAMPLE 0 Year = 1 1 Month = 0 1 Day = 13 Date = 13 April 2015 © ISO 01 – All rights reserved I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n 35 ISO 1007-2 :2 015(E) E.2.19 Data item 20: Fill station ship date (optional) Date of shipment of cylinder by manufacturer: Fill station ship date Bits 16 bit 15 14 13 12 11 10 Year (0 –1 27 ) Month (0 –15 ) Day (0–31) Default value: Year = 0, Month = 1, Day = Year: to 9 is effective range It is interpreted that or more is in the 19 0 s and less than is in the 0 s Month: to 12 is effective range Day: to 31 is effective range E XAMPLE 0 1 0 Year = 0 1 Day = 13 Month = Date = 13 April 2012 E.2.20 Data item 21: Return due date (optional) Date of return due: Return due date Bits 16 bit 15 14 13 12 11 10 Year (0 –1 27 ) Month (0 –15 ) Day (0–31) Default value: Year = 0, Month = 1, Day = Year: to 9 is effective range It is interpreted that or more is in the 19 0 s and less than is in the 0 s Month: to 12 is effective range Day: to 31 is effective range E XAMPLE 0 Year = 1 1 Month = 0 1 Day = 13 Date = 13 April 2015 36 I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n © ISO 01 – All rights reserved ISO 1007-2 :2 015(E) E.2.21 Data item 22: Dealer ship date (optional) Date of shipment of cylinder by dealer: Dealer ship date Bits 16 bit 15 14 13 12 11 10 Year (0 –1 27 ) Month (0 –1 ) Day (0–31) Default value: Year = 0, Month = 1, Day = Year: to 9 is effective range It is interpreted that or more is in the 19 0 s and less than is in the 0 s Month: to 12 is effective range Day: to 31 is effective range E XAMPLE 0 1 0 Year = 0 1 Day = 13 Month = Date = 13 April 201 E.2.22 Data item 23: GC delivery date (optional) Date of delivery of cylinder: GC delivery date Bits 16 bit 15 14 13 12 11 10 Year (0 –1 27 ) Month (0 –1 ) Day (0–31) Default value: Year = 0, Month = 1, Day = Year: to 9 is effective range It is interpreted that or more is in the 19 0 s and less than is in the 0 s Month: to 12 is effective range Day: to 31 is effective range E XAMPLE 0 Year = 1 0 Month = 0 1 Day = 13 Date = 13 April 201 © ISO 01 – All rights reserved I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n 37 ISO 1007-2 :2 015(E) E.2.23 Data item 24: Empty GC collection date (1) (optional) Date of collecting gas cylinder from the last delivery point: Empty GC collection date Bits 16 bit 15 14 13 12 11 10 Year (0 –1 27 ) Month (0 –15 ) Day (0–31) Default value: Year = 0, Month = 1, Day = Year: to 9 is effective range It is interpreted that or more is in the 19 0 s and less than is in the 0 s Month: to 12 is effective range Day: to 31 is effective range E XAMPLE 0 1 0 Year = 0 1 1 Day = 13 Month = Date = 13 April 2012 E.2.24 Data item 25: Empty GC collection date (2) (optional) Date of collecting gas cylinder from the intermediate delivery point: Empty GC collection date Bits 16 bit 15 14 13 12 11 10 Year (0 –1 27 ) Month (0 –15 ) Day (0–31) Default value: Year = 0, Month = 1, Day = Year: to 9 is effective range It is interpreted that or more is in the 19 0 s and less than is in the 0 s Month: to 12 is effective range Day: to 31 is effective range E XAMPLE 0 Year = 1 0 Month = 0 1 Day = 13 Date = 13 April 2012 38 I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n © ISO 01 – All rights reserved ISO 1007-2 :2 015(E) E.2.25 Data item 26: Operator code fill in GC delivery date (optional) Code of the operator who fills in the date of delivery of cylinder: (binary 0–4 095) Bits Variables Type Default value 12 96 Binary Use the code allocated by JIMGA for those who need to write information on the RF tag (manufacturer, dealer or retesting company etc.) E.2.26 Data item 27: Operator code fill in empty GC collection date (1) (optional) Code of the operator who fills in the date of collection of empty cylinder (1): (binary 0–4 095) Bits Variables Type Default value 12 96 Binary Use the code allocated by JIMGA for those who need to write information on the RF tag (manufacturer, dealer or retesting company etc.) E.2.27 Data item 28: Operator code fill in empty GC collection date (2) (optional) Code of the operator who fills in the date of collection of empty cylinder (2): (binary 0–4 095) Bits Variables Type Default value 12 96 Binary Use the code allocated by JIMGA for those who need to write information on the RF tag (manufacturer, dealer or retesting company etc.) E.2.28 Data item 29: GC manufacture date (optional) Date of manufacture of gas cylinder: GC manufacture date Bits 16 bit 15 14 13 12 11 10 Year (0 –1 27 ) Month (0 –1 ) Day (0–31) Default value: Year = 0, Month = 1, Day = Year: to 9 is effective range It is interpreted that or more is in the 19 0 s and less than is in the 0 s Month: to 12 is effective range Day: to 31 is effective range E XAMPLE 0 Year = 65 0 1 Month = 0 1 Day = 13 Date = 13 April 1965 © ISO 01 – All rights reserved I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n 39 ISO 1007-2 :2 015(E) E.2.29 Data item 30: GC status, filled/empty (optional) Code of filled/empty cylinder: (binary 0–1) Bits Variables Type Default value Binary Condition Code Empty cylinder or cylinder with residual gas Filled cylinder E.2.30 Data item 31: GC use kind (optional) Kind of use: (binary 0–15) Bits Variables Type Default value 16 Binary 15 14 13 12 11 10 GC use kind Code GC use kind For industrial For medical For food additive Specialty gas Standard gas 5–15 Reserved E.2.31 Data item 32: Free area (optional) Free area for your system: (binary 0–16 777 215) 40 I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n Bits Variables Type Default value 24 16 777 216 Binary © ISO 2015 – All rights reserved ISO 1007-2 :2 015(E) Bibliography [1] UN Recommendations on the Transport of Dangerous Goods — Model Regulations [2] ISO/IEC 8824-2, Information technology — Abstract Syntax Notation One (ASN.1): Information object specification [3] , a s a me nde d ISO/IEC 8824-3, Information technology — Abstract Syntax Notation One (ASN.1): Constraint specification [4] ISO/IEC 8824-4, Information technology — Abstract Syntax Notation One (ASN.1): Parameterization of ASN.1 specifications [5] ISO/IEC 18000 (all parts), Information technology — Radio frequency identification for item management © I S O – Al l ri gh ts re s e rve d I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n 41 ISO 1007-2 :2 015(E) ICS 23.020.30 Price based on 41 pages © ISO 2015 – All rights reserved I n tern ati o n al Org an i z ati o n fo r S tan d ard i z ati o n