ASTM F2207-06(2013)

NOTICE: This standard has either been superseded and replaced by a new version or withdrawn.
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Designation:F2207 −06 (Reapproved 2013) An American National Standard
Standard Specification for
Cured-in-Place Pipe Lining System for Rehabilitation of
Metallic Gas Pipe
This standard is issued under the fixed designation F2207; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope maintainthestructuralintegrityofthehostpipesothattheliner
does not become free standing.
1.1 This specification covers requirements and method of
testing for materials, dimensions, hydrostatic burst strength, 1.3 MPLCIPliners (SectionA) can be installed in partially
chemical resistance, adhesion strength and tensile strength deteriorated pipe as defined in 3.2.10. Even for low pressure
properties for cured-in-place (CIP) pipe liners installed into gas distribution systems, which typically operate at less than 1
existing metallic gas pipes, ⁄4 to 48 in. nominal pipe size, for psig, MPL CIP liners are not intended for use as a stand-alone
gas carrier pipe but rely on the structural integrity of the host
renewal purposes. The maximum allowable operating pressure
(MAOP) of such renewed gas pipe shall not exceed a pressure pipe. Therefore, the safe use of cured-in-place pipe lining
technology for the rehabilitation of existing cast iron, steel, or
of 300 psig (2060 kPa). The cured-in-place pipe liners covered
by this specification are intended for use in pipelines transport- other metallic gas piping systems, operating at pressures up to
100 psig, is contingent on a technical assessment of the
ing natural gas, petroleum fuels (propane-air and propane-
butane vapor mixtures), and manufactured and mixed gases, projected operating condition of the pipe for the expected 30 to
50 year life of the CIP liner. Cured-in-place pipe liners are
whereresistancetogaspermeation,groundmovement,internal
corrosion, leaking joints, pinholes, and chemical attack are intended to repair/rehabilitate structurally sound pipelines
having relatively small, localized defects such as localized
required.
corrosion, welds that are weaker than required for service, or
1.2 The medium pressure (up to 100 psig) cured-in-place
loose joints (cast iron pipe), where leaks might occur.
pipe liners (Section A) covered by this specification are
1.3.1 HPL CIP liners (Section B) are intended for use only
intended for use in existing structurally sound or partially
in existing structurally sound steel gas pipe as defined in
deteriorated metallic gas pipe as defined in 3.2.10. The high
3.2.10.HPLCIPlinersarenotintendedforuseasastand-alone
pressure (over 100 psig up to 300 psig) cured-in-place pipe
gas carrier pipe but rely on the structural integrity of the host
liners (Section B) covered by this specification are intended for
pipe. Therefore, the safe use of cured-in-place pipe lining
use only in existing structurally sound steel gas pipe as defined
technology for the rehabilitation of existing steel gas piping
in 3.2.10. CIPliners are installed with limited excavation using
systems, operating at pressures up to 300 psig, is contingent on
an inversion method (air or water) and are considered to be a
a technical assessment of the projected operating condition of
trenchlesspipelinerehabilitationtechnology.Theinvertedliner
the pipe for the expected 30 to 50 year life of the CIP liner.
is bonded to the inside wall of the host pipe using a compatible
adhesive (usually an adhesive or polyurethane) in order to 1.4 The values stated in inch-pound units are to be regarded
as standard. No other units of measurement are included in this
prevent gas migration between the host pipe wall and the CIP
standard.
liner and, also, to keep the liner from collapsing under its own
weight.
1.5 This standard does not purport to address all of the
1.2.1 Continued growth of external corrosion, if undetected
safety concerns, if any, associated with its use. It is the
and unmitigated, could result in loss of the host pipe structural
responsibility of the user of this standard to establish appro-
integrity to such an extent that the liner becomes the sole
priate safety and health practices and determine the applica-
pressure bearing element in the rehabilitated pipeline structure.
bility of regulatory requirements prior to use.
TheCIPlinerisnotintendedtobeastand-alonepipeandrelies
2. Referenced Documents
on the structural strength of the host pipe. The operator must
2.1 ASTM Standards:
D123 Terminology Relating to Textiles
This specification is under the jurisdiction ofASTM Committee F17 on Plastic
Piping Systems and is the direct responsibility of Subcommittee F17.60 on Gas. For referenced ASTM standards, visit the ASTM website, www.astm.org, or
Current edition approved Aug. 1, 2013. Published October 2013. Originally contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
approved in 2002. Last previous edition approved in 2006 as F2207 – 06. DOI: Standards volume information, refer to the standard’s Document Summary page on
10.1520/F2207-06R13. the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
F2207−06 (2013)
D543 Practices for Evaluating the Resistance of Plastics to 3.2.6 flexible tubing—the flexible tube is the tubing material
Chemical Reagents inverted into the host pipe and is used to carry and distribute
D883 Terminology Relating to Plastics the adhesive. For a two-component system, the flexible tubing
D1598 Test Method for Time-to-Failure of Plastic Pipe consists of a cylindrical jacket coated with an elastomer skin.
Under Constant Internal Pressure For a three-component system, it is the same as the elastomer
D1600 Terminology forAbbreviatedTerms Relating to Plas- skin.
tics
3.2.7 high-pressure liner (HPL)—a CIP liner only intended
D1763 Specification for Epoxy Resins
forstructurallysoundsteelpipeinsizes4in.andlargerwithan
D2240 Test Method for Rubber Property—Durometer Hard-
MAOP greater than 100 psig up to 300 psig. High pressure
ness
liners (HPL) are only intended for steel pipe that has a
D2837 Test Method for Obtaining Hydrostatic Design Basis
maintained cathodic protection system with annual reads per
forThermoplasticPipeMaterialsorPressureDesignBasis
local codes, such as CFR 49 Part 192, and other mandated
for Thermoplastic Pipe Products
maintenance, such as leak surveys.The PDB testing conducted
D3167 Test Method for Floating Roller Peel Resistance of
on high pressure liners is intended for the extreme case if holes
Adhesives
occur in the steel pipe that are not detected by the cathodic
D3892 Practice for Packaging/Packing of Plastics
protection maintenance system. Corrosion monitoring per CFR
D4848 Terminology Related to Force, Deformation and
49 Part 192 shall be conducted annually to track changes in
Related Properties of Textiles
required readings and confirm there is no active corrosion
D4850 Terminology Relating to Fabrics and Fabric Test
3.2.8 jacket—the jacket is a textile product that is manufac-
Methods
tured into a cylindrical form. It is made of synthetic materials,
F412 Terminology Relating to Plastic Piping Systems
typically polyester, and provides the tensile strength and
2.2 Other Standards:
flexibility necessary to resist the specified sustained pressure
CFR 49 Part 192
when installed in partially deteriorated pipe as defined in
3.2.10.
3. Terminology
3.2.9 medium-pressure liner (MPL) —a CIP liner intended
3.1 General—Definitions are in accordance with those set
for all types of structurally sound or partly deteriorated metal
forth in Terminologies D123, D883, D4848, D4850, and F412.
pipes and for all applicable sizes of pipe with an MAOPof 100
Abbreviations are in accordance with Terminology D1600,
psig or less. MPL liners are relatively flexible.
unless otherwise indicated.
3.2.10 partially deteriorated metallic pipe—pipe that has
3.2 Definitions of Terms Specific to This Standard:
either been weakened or is leaking because of localized
3.2.1 adhesive system—the adhesive system is typically a corrosion, welds that are weaker than required for service,
two-part adhesive or polyurethane consisting of a resin and a
deteriorated joints (cast iron), etc. Partially deteriorated pipe
hardener. The flexible tubing, after wet-out, is inserted into the cansupportthesoilandinternalpressurethroughoutthedesign
pipeline to be rehabilitated using an inversion method. After
life of the composite except at the relatively small local points
the inversion is complete, the adhesive is cured using either identified above.
ambient or thermal processes.
3.2.11 three-component system—a CIP pipe lining system
3.2.2 cleaned pipe—pipe whose inside wall, that which is comprised of three separate components, which are the elasto-
bonded to the CIP pipe liner, has been cleaned down to bare mer skin, the jacket, and the adhesive.
metal and is free of tars, pipeline liquids, oils, corrosion
3.2.12 two-component system—a CIP pipe lining system
by-products, and other materials that could impair the bonding
comprised of two separate components, which are the flexible
of the liner to the pipe wall.
tube and the adhesive.
3.2.3 composite—the composite is the combination of the
3.2.13 wet-out—the process of placing the adhesive system
cured adhesive system, the elastomer skin, and the jacket.
intotheflexibletubinganduniformlydistributingitpriortothe
inversion process.
3.2.4 elastomer skin—the elastomer skin is a membrane,
typically made of polyurethane or polyester, allowing for both
4. Materials
inversion of the liner during the installation process and
pressure tight in-service operation. When the flexible tubing is
4.1 The materials shall consist of the flexible tubing, jacket,
inverted into the pipeline to be rehabilitated, the elastomer skin
and the adhesive system. The combination of materials used in
becomes the inside surface of the newly rehabilitated pipeline,
both the flexible tubing and the adhesive system shall depend
directly exposed to the gas being transported.
on the desired design characteristics of the composite. All
3.2.5 expansion ratio table—a table of measured diameters materials shall be compatible for natural gas service. Because
of the flexible tubing at increments of pressure, supplied by the CIP pipe liners are both multi-component and multi-material
manufacturer. The expansion ratio is used to calculate the systems, it becomes necessary to specify minimum material
pressure required to fit the flexible tubing against the pipe wall performance requirements for the liner composite rather than
and to determine the applicable range of pipe I.D. for a given specific material testing requirements for the individual com-
diameter flexible tubing. ponents. These requirements are outlined in Section 5.
F2207−06 (2013)
4.1.1 Flexible Tubing—For a two-component system, the elastomer skin shall be rolled onto reels designed to provide
flexible tubing consists of a jacket with an elastomer skin that protection during shipping and handling.The jacket may either
functions as a gas barrier. For a three-component system, the be rolled onto reels or folded into boxes.
elastomerskinistheflexibletubing.Theelastomerskininboth 5.1.2 Dimensions—An expansion ratio table, as defined in
systems is typically made of polyurethane or polyester. The
3.2.5, including nominal size and length, shall be attached to
flexible tubing is fit tightly against the inner surface of the each roll of flexible tubing or jacket and elastomer skin prior to
existing pipe by diametrical expansion using air or water
shipment from the manufacturer. All material dimensions and
pressure and bonded to the inner pipe wall with an adhesive. physical properties must at least meet the minimum
4.1.2 Jacket—The jacket is made of polyester or other
specifications, requirements, or tolerances assumed in estab-
synthetic materials compatible with the application. The jacket lishing the strength tests under Section 6.
provides the necessary strength to the composite to meet the
5.1.3 Chemical Resistance—The jacket and the elastomer
required design characteristics, for example, resistance to
skin materials shall be compatible with the liquids listed in
internal and external pressure, resistance to earth movement,
Table 1 and tested in accordance with Practice D543, Practice
and diametrical expandability.
A, Procedure I. Neither tensile strength nor elongation of any
4.1.3 Elastomer Skin—The elastomer skin holds the adhe-
of the components shall change more than 20 %. Weight of the
sive system inside the flexible tubing during the wet-out,
test specimen after testing shall not have increased by more
inversion, and curing. During the inversion and curing, the
than 14 % or decreased by more than 3 %. This test shall be a
elastomer skin holds the air, water, or steam pressure inside the
qualification test to be performed once for each class or
flexible tubing. When the flexible tubing is inverted into the
pressure rating of installed pipe liner.
existing pipe, the elastomer skin becomes the inside surface of
NOTE 1—These tests are only an indication of what will happen as a
the lined pipe. Upon completion of the installation, the
result of short-term exposure to these chemicals. For long-term results,
elastomer skin is directly exposed to the gas being transported
additional testing is required.
and forms a gas barrier. The elastomer skin shall have a high
5.1.4 Elastomeric Peeling Strength—The peeling strength
chemical resistance to the materials it is in contact with as
between the jacket and the elastomer skin shall meet or exceed
defined in 5.1.3. For two-component systems, the elastomer
7.0 lb/in. (1.2 kg/cm) when measured in accordance with Test
skinisextrudedorotherwiseplacedontheoutsideofthejacket
Method D3167.
during the manufacture of the flexible tubing.
5.1.5 Physical Properties—Fortwo-componentsystems,the
4.1.4 Adhesive System—The adhesive is a two-part system
design pressure of the flexible tubing shall be sufficient to
composed of a resin and a hardener. The adhesive formulation
withstand the required installation, testing, and operating
can be modified as necessary to meet the curing time, strength,
pressures and to form the required composite. For three-
and application requirements specified for the lining installa-
component systems, the design pressure of the elastomer skin
tion. The cured adhesive system, in combination with the
or flexible tube shall be sufficient to withstand the installation
flexible tubing, forms the composite. Either
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