ISO 11515:2013
(Main)Gas cylinders — Refillable composite reinforced tubes of water capacity between 450 L and 3000 L — Design, construction and testing
Gas cylinders — Refillable composite reinforced tubes of water capacity between 450 L and 3000 L — Design, construction and testing
ISO 11515:2013 specifies minimum requirements for the design, construction and performance testing of composite reinforced tubes between 450 l and 3 000 l water capacity, for transport, storage and use of compressed or liquefied gases with test pressures up to and including 1600 bar with a design life of at least 15 years and less than or equal to 30 years. The expected service temperatures are between -40 °C and +65 °C. The tubes defined are one of three types: Type 2 - a hoop wrapped tube with a load sharing metal liner and composite reinforcement on the cylindrical portion only. Type 3 - a fully wrapped tube with a load sharing metal liner and composite reinforcement on both the cylindrical portion and the dome ends. Type 4 - a fully wrapped tube with a non-load sharing liner and composite reinforcement on both the cylindrical portion and the dome ends. The Type 4 tubes are not intended to contain toxic, oxidizing or corrosive gases. ISO 11515:2013 is limited to tubes with composite reinforcement of carbon fibre or aramid fibre or glass fibre (or a mixture thereof) in a matrix. Composite tubes can be used alone or in batteries to equip trailers or skids (ISO modules) or multiple element gas containers (MEGC) for the transportation and distribution of gases. ISO 11515:2013 does not include consideration of any additional stresses that can occur during service or transport, (e.g. torsional / bending stresses). However it is important that the stresses associated with mounting the tube are considered by the assembly manufacturer and the tube manufacturer. The design life of tubes according to ISO 11515:2013 for transport of dangerous goods can be limited by the applicable regulations.
Bouteilles à gaz — Bouteilles tubulaires en composite renforcé rechargeables d'une capacité de 450 L à 3000 L — Conception, construction et essais
General Information
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Standards Content (Sample)
INTERNATIONAL ISO
STANDARD 11515
First edition
2013-07-15
Gas cylinders — Refillable composite
reinforced tubes of water capacity
between 450 L and 3000 L — Design,
construction and testing
Bouteilles à gaz — Bouteilles tubulaires en composite renforcé
rechargeables d’une capacité de 450 L à 3000 L — Conception,
construction et essais
Reference number
ISO 11515:2013(E)
©
ISO 2013
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ISO 11515:2013(E)
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ISO 11515:2013(E)
Contents Page
Foreword .iv
Introduction .v
1 Scope . 1
2 Normative references . 1
3 Terms and definitions . 2
4 Symbols . 5
5 Inspection and testing . 5
6 Materials . 5
6.1 Liner materials . 5
6.2 Composite overwrap . 6
7 Design and manufacture . 6
7.1 General . 6
7.2 Design submission . 7
7.3 Manufacturing . 8
8 Type approval procedure . 9
8.1 General . 9
8.2 Prototype tests . 9
8.3 New design .10
8.4 Design variants .11
8.5 Type approval test procedures and criteria .12
8.6 Failure of type approval tests .29
9 Inspection and testing at time of manufacture .29
9.1 Liners for Type 2 and Type 3 tubes .29
9.2 Liners for Type 4 tubes .29
9.3 Failure of liner batch tests .30
9.4 Overwrap materials .30
9.5 Composite tube .31
9.6 Failure of batch tests .31
10 Tube marking .32
10.1 General .32
10.2 Additional marking .32
Annex A (informative) Examples of design approval certificate .33
Annex B (informative) Specimen test reports .34
Annex C (normative) Ultrasonic inspection for seamless steel liners and metal tubing .36
Bibliography .41
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ISO 11515:2013(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 1. 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 2. 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 identified during the development of the document will be in the Introduction and/or
on the ISO list of patent declarations received. 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.
The committee responsible for this document is ISO/TC 58, Gas cylinders, Subcommittee SC 3, Cylinder design.
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ISO 11515:2013(E)
Introduction
The purpose of ISO 11515 is to provide a specification for the design, manufacture, inspection and testing
of composite tubes for worldwide usage. The objective is to balance design and economic efficiency
against international acceptance and universal utility.
ISO 11515 aims to eliminate the concern about climate, duplicate inspection and restrictions currently
existing because of lack of definitive International Standards and should not be construed as reflecting
on the suitability of the practice of any nation or region.
ISO 11515 addresses the general requirements on design, construction and initial inspection and testing
of pressure receptacles of the United Nations Recommendations on the Transport of Dangerous Goods
Model Regulations.
Annexes A and B of ISO 11515 are for information only.
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INTERNATIONAL STANDARD ISO 11515:2013(E)
Gas cylinders — Refillable composite reinforced tubes
of water capacity between 450 L and 3000 L — Design,
construction and testing
1 Scope
This International Standard specifies minimum requirements for the design, construction and
performance testing of composite reinforced tubes between 450 l and 3 000 l water capacity, for
transport, storage and use of compressed or liquefied gases with test pressures up to and including
1600 bar with a design life of at least 15 years and less than or equal to 30 years. The expected service
temperatures are between −40 °C and +65 °C.
The tubes defined are one of three types:
Type 2: a hoop wrapped tube with a load sharing metal liner and composite reinforcement on the
cylindrical portion only.
Type 3: a fully wrapped tube with a load sharing metal liner and composite reinforcement on both the
cylindrical portion and the dome ends.
Type 4: a fully wrapped tube with a non-load sharing liner and composite reinforcement on both the
cylindrical portion and the dome ends.
The Type 4 tubes manufactured and tested to this International Standard are not intended to contain
toxic, oxidizing or corrosive gases.
This International Standard is limited to tubes with composite reinforcement of carbon fibre or aramid
fibre or glass fibre (or a mixture thereof) in a matrix.
Composite tubes can be used alone or in batteries to equip trailers or skids (ISO modules) or multiple
element gas containers (MEGC) for the transportation and distribution of gases. This International
Standard does not include consideration of any additional stresses that can occur during service or
transport, (e.g. torsional / bending stresses). However it is important that the stresses associated with
mounting the tube are considered by the assembly manufacturer and the tube manufacturer.
NOTE The design life of tubes according to this International Standard for transport of dangerous goods can
be limited by the applicable regulations.
2 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.
ISO 306, Plastics — Thermoplastic materials — Determination of Vicat softening temperature (VST)
ISO 527-1, Plastics — Determination of tensile properties — Part 1: General principles
ISO 527-2, Plastics — Determination of tensile properties — Part 2: Test conditions for moulding and
extrusion plastics
ISO 3341, Textile glass — Yarns — Determination of breaking force and breaking elongation
ISO 4624, Paints and varnishes — Pull-off test for adhesion
ISO 6506-1, Metallic materials — Brinell hardness test — Part 1: Test method
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ISO 11515:2013(E)
ISO 6508-1, Metallic materials — Rockwell hardness test — Part 1: Test method
ISO 6892-1, Metallic materials — Tensile testing — Part 1: Method of test at room temperature
ISO 7225, Gas cylinders — Precautionary labels
ISO 7866, Gas cylinders — Refillable seamless aluminium alloy gas cylinders — Design, construction and testing
ISO 9227:2012, Corrosion tests in artificial atmospheres — Salt spray tests
ISO 9712, Non-destructive testing — Qualification and certification of NDT personnel
ISO 9809-1, Gas cylinders — Refillable seamless steel gas cylinders — Design, construction and testing —
Part 1: Quenched and tempered steel cylinders with tensile strength less than 1 100 MPa
ISO 9809-2, Gas cylinders — Refillable seamless steel gas cylinders — Design, construction and testing —
Part 2: Quenched and tempered steel cylinders with tensile strength greater than or equal to 1 100 MPa
ISO 9809-3, Gas cylinders — Refillable seamless steel gas cylinders — Design, construction and testing —
Part 3: Normalized steel cylinders
ISO 10618, Carbon fibre — Determination of tensile properties of resin-impregnated yarn
ISO 11114-1, Gas cylinders — Compatibility of cylinder and valve materials with gas contents — Part 1:
Metallic materials
ISO 11114-2, Gas cylinders — Compatibility of cylinder and valve materials with gas contents — Part 2:
Non-metallic materials
ISO 11120, Gas cylinders — Refillable seamless steel tubes of water capacity between 150 l and 3000 l —
Design construction and testing
ISO 13341, Gas cylinders — Fitting of valves to gas cylinders
ISO 13769, Gas cylinders — Stamp marking
ASTM D 522-93a, Standard Test Methods for Mandrel Bend Test of Attached Organic Coatings
ASTM D1308, Standard Test Method for Effect of Household Chemicals on Clear and Pigmented Organic Finishes
ASTM D2794, Standard Test Method for Resistance of Organic Coatings to the Effects of Rapid
Deformation (Impact)
ASTM D3170, Standard Test Method for Chipping Resistance of Coatings
ASTM D7269, Standard Test Methods for Tensile Testing of Aramid Yarns
3 Terms and definitions
For the purposes of this document, the following terms and definitions apply.
3.1
aramid fibre
continuous filaments of aramid laid up in tow form, used for reinforcement
3.2
autofrettage
pressure application procedure which strains the metal liner past its yield point sufficient to cause
permanent plastic deformation, and results in the liner having compressive stresses and the fibres
having tensile stresses when at zero internal gauge pressure
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ISO 11515:2013(E)
3.3
batch
collective term for a set of homogeneous items or material
Note 1 to entry: The number of items in a batch can vary according to the context in which the term is used.
3.4
batch of load sharing liners
quantity of up to 30 liners of the same nominal diameter, length, thickness and design, made successively
from the same material cast (heat) and processed in the same heat treatment equipment (i.e. a continuous
furnace process or a single furnace charge) using the same heat treatment parameters
3.5
batch of non-metallic liners
quantity of non-metallic liners of the same nominal diameter, length, thickness and design, made
successively and subjected to the same continuous manufacturing process
3.6
batch of non-load sharing metal liners or metal bosses
quantity of non-load sharing metal liners or metal bosses of the same nominal diameter, length,
thickness and design, made successively from the same material cast (heat) and processed in the same
heat treatment equipment using the same heat treatment parameters
3.7
batch of finished tubes
production quantity of up to 200 finished tubes successively produced (plus finished tubes required for
destructive testing), of the same nominal diameter, length, thickness and design
Note 1 to entry: The batch of finished tubes can contain different batches of liners, fibres and matrix materials.
3.8
burst pressure
highest pressure reached in a tube or liner during a burst test
3.9
carbon fibre
continuous filaments of carbon laid up in tow form, used for reinforcement
3.10
composite overwrap
combination of fibres and matrix used to reinforce the tube, including any barrier or protective layers
that are a permanent part of the design
3.11
dedicated gas service
service in which a tube is to be used only with specified gas or gases
3.12
equivalent fibre
fibre equivalent to a fibre used in a previously prototype tested tube
3.13
exterior coating
layers of material applied to the tube as protection or for cosmetic purposes
Note 1 to entry: The coating can be transparent or opaque.
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ISO 11515:2013(E)
3.14
equivalent liner
liner manufactured from the same nominal raw materials, using the same process of manufacture and
having the same physical structure and the same nominal physical properties (within ± 5 %) of the
approved liner design
3.15
glass fibre
continuous filaments of glass laid up in tow form, used for reinforcement
3.16
leak
-3
escape of gas at a rate greater than 5×10 mbar.l/s through a defect rather than permeation
3.17
liner
inner portion of the composite tube, whose purpose is both to contain the gas and transmit the gas
pressure to the fibres
3.18
load sharing liner
liner that has a burst pressure greater than or equal to 5 % of the nominal burst pressure of the finished
composite tube
3.19
non-load-sharing liner
liner which has a burst pressure less than 5 % of the nominal burst pressure of the finished composite tube
3.20
matrix
material that is used to bind and hold the fibres in place
3.21
minimum design burst pressure
minimum burst pressure specified by the manufacturer and that shall be achieved during a burst test
3.22
tube
transportable pressure receptacle of a water capacity exceeding 150 litres
3.23
representative composite tube
a shorter tube with the same nominal diameter, and manufactured using the same materials and
manufacturing technique, and using a representative wrapping pattern (same number of strands and
same number of layers) so as to represent an equivalent stress compared to a full scale prototype
3.24
tubing
hollow cylindrical body of metal or other material, used for conveying or containing liquids or gases
3.25
Type 2 tube
hoop wrapped tube with a load sharing metal liner and composite reinforcement on the cylindrical
portion only
3.26
Type 3 tube
fully wrapped tube with a load sharing metal liner and composite reinforcement on both cylindrical
portion and dome ends
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ISO 11515:2013(E)
3.27
Type 4 tube
fully wrapped tube with a non-load sharing liner and composite reinforcement on both cylindrical
portion and dome ends
4 Symbols
p Burst pressure of finished tube bar
b
p Test pressure bar
h
p Maximum developed pressure at 65 °C bar
max
p Working pressure bar
w
5 Inspection and testing
ISO 11515 is intended to be used under a variety of national regulatory regimes but has been written
so that it is suitable for use with the conformity assessment system of the UN Model Regulations for the
Transportation of Dangerous Goods. Attention is drawn to requirements in specified relevant national
regulations of the country (countries) where the tubes are intended to be used that might override the
requirements given in this International Standard. To ensure that the tubes conform to this International
Standard, they shall be subject to inspection and testing in accordance with Clauses 6, 7, 8 and 9 by an
inspection body (hereafter referred to as “the inspector”) authorized to do so.
Equipment used for measurement, testing and examination during production shall be maintained and
calibrated within a documented quality management system.
6 Materials
6.1 Liner materials
6.1.1 Load sharing liner materials shall conform in all relevant respects to the appropriate
International Standards:
a) seamless steel liners: ISO 9809-1, ISO 9809-2, ISO 9809-3 or ISO 11120 as appropriate;
b) seamless aluminium alloy liners: ISO 7866.
Relevant sections are those covering materials, thermal treatments, neck design, construction and
workmanship, mechanical tests. Design requirements are excluded since these are specified by the
manufacturer for the design of the composite tube (see 7.2.2).
6.1.1.1 The composite tube manufacturer shall verify that each new batch of materials has the specified
properties and qualities, and shall maintain records so that the cast of material and the heat treatment
batch (where applicable) used for the manufacture of each tube can be identified. A certificate of
conformance from the liner material manufacturer is considered acceptable for the purposes of
verification.
6.1.1.2 The liner shall be manufactured from a metal or alloy suitable for the gas to be contained in
accordance with ISO 11114-1.
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ISO 11515:2013(E)
6.1.1.3 When a neck ring is provided, it shall be of a material compatible with that of the tube, and shall
be securely attached by a method appropriate to the liner material.
Non-load sharing liner materials shall conform in all relevant respects to the appropriate standards, as
follows:
a) The liner (including metal boss) shall be manufactured from a material suitable for the gas to be
contained in accordance with ISO 11114-1 and ISO 11114-2.
b) Metal bosses attached to a non-metallic liner shall fulfil the performance requirements of this
International Standard.
c) The tensile yield strength and ultimate elongation of plastic liner material shall be determined at
−50 °C in accordance with ISO 527-2.The test results shall demonstrate the ductile properties of
the plastic liner material at temperatures of −50 °C or lower by meeting the values specified by the
manufacturer.
d) Polymeric materials from finished liners shall be tested in accordance with a method described in
ISO 306. The softening temperature shall be at least 100 °C.
6.2 Composite overwrap
6.2.1 The overwrap filament materials shall be carbon fibre or aramid fibre or glass fibre (or any
mixture thereof).
6.2.2 The resin matrix shall be a polymer suited to the application, environment and intended life of the
product, e.g. epoxy or modified epoxy with amine or anhydride curing agent, vinyl esters and polyesters.
6.2.3 The supplier of the filament material and the resin matrix system component materials shall
provide sufficient documentation for the composite tube manufacturer to be able to identify fully the
batch of materials used in the manufacture of each tube.
6.2.4 The composite tube manufacturer shall verify that each new batch of materials has the correct
properties and is of satisfactory quality, and maintain records from which the batch of materials used
for the manufacture of each tube can be identified. A certificate of conformance from the material
manufacturer is considered acceptable for the purposes of verification.
6.2.5 Batches of materials shall be identified and documented to the satisfaction of the inspector.
6.2.6 The manufacturer shall ensure there is no adverse reaction between the liner and the reinforcing
fibre, e.g. by the application of a suitable protective coating to the liner prior to the wrapping process
(if necessary).
NOTE Glass fibre reinforced composite tubes can be susceptible to chemical attack and degradation after
being in contact with aggressive acids (e.g. battery acid).
7 Design and manufacture
7.1 General
7.1.1 A Type 2 composite tube shall comprise:
a) an internal metal liner with one or two openings along the central axis only, which carries all the
longitudinal load and part of the circumferential load;
b) the liner, designed to withstand a burst pressure greater than 0,85 of the test pressure of the
finished tube.
c) a composite overwrap formed by layers of continuous fibres in a matrix along the parallel portions
of the tube sidewall;
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ISO 11515:2013(E)
d) an optional exterior coating to provide external protection. When this is an integral part of the
design it shall be permanent.
7.1.2 A Type 3 composite tube shall comprise:
a) an internal metal liner with one or two openings along the central axis only, which carries part of
the longitudinal and circumferential load;
b) a composite overwrap formed by layers of continuous fibres in a matrix;
c) an optional exterior coating to provide external protection. When this is an integral part of the
design it shall be permanent.
7.1.3 A Type 4 composite tube shall comprise:
a) an internal metal or non-metallic non-load sharing liner with one or two openings along the
central axis only;
b) metallic boss(es) for thread connections, where these are part of the design;
c) a composite overwrap formed by layers of continuous fibres in a matrix;
d) an optional exterior coating to provide external protection. When this is an integral part of the
design it shall be permanent.
7.2 Design submission
7.2.1 The design submission for each new design of tube shall include a detailed drawing, along with
documentation of the design including, manufacturing and inspection particulars as detailed in 7.2.2,
7.2.3, and 7.2.4.
The design submission will cover a design family of composite tubes of the same diameter and pressure
with different cylindrical lengths from 2× diameter and up to 5× the length of the representative
composite tube and with a water capacity between 450 and 3 000 litre.
7.2.2 Documentation for the liner and/or metal boss(es) shall include:
a) Material details, including limits of chemical analysis;
b) dimensions, minimum thickness, straightness and out of roundness with tolerances;
c) process and specification of manufacture;
d) heat-treatment, temperatures, duration and tolerances (where applicable);
e) inspection procedures (minimum requirements);
f) material properties (including hardness for Type 2 and Type 3 tubes);
g) minimum design burst pressure (for Type 2 and Type 3 tube liners);
h) dimensional details of valve threads;
i) method of sealing boss to liner for Type 4 tubes.
7.2.3 Documentation for the composite overwrap shall include:
a) fibre material, specification and mechanical properties requirements;
b) minimum composite thickness;
c) resin system - main components and resin bath temperature where applicable;
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ISO 11515:2013(E)
d) thermoplastic matrix system – main component materials, specifications and process temperatures;
e) thermosetting matrix – specifications (including resin, curing agent and accelerator), and resin bath
temperature where applicable;
f) overwrap construction including the number of strands used, number of layers, and layer orientation;
g) curing process, temperatures, duration and tolerances.
7.2.4 Documentation for the composite tube shall include:
a) water capacity in litres;
b) dimensions, minimum thickness, straightness and out of roundness with tolerances;
c) list of intended contents if intended for dedicated gas service;
d) working pressure p which shall not exceed 2/3 test pressure;
w
e) composite tube test pressure, p ;
h
f) allowable range of elastic expansions and permanent expansions (if appropriate) for the design
when volumetric expansion test is used (See 9.5.4), to the satisfaction of the Competent Authority;
g) maximum developed pressure at 65 °C for specific dedicated gas(es) p ;
max
h) minimum design burst pressure;
i) design life in years between 15 and 30 years;
j) autofrettage pressure and approximate duration (where applic
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