61_QuizizzAPI 1104 21 2016.pdf

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WELDING OF PIPELINES AND RELATED FACILITIES

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53

2 mm -0/+0.5 mm

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1 mm

NOTE HAZ hardness impressions shall be entirely within the heat-affected zone and located as
close as possible to the fusion boundary (between the weld metal and heat-affected zone).

Figure 25—Hardness Locations for Cover Pass Repair Procedure at Fusion Line
5

/64LQí1/64 in.
PPíPP

3

/64 in.
(1 mm)

NOTE Heat-affected zone (HAZ) hardness impressions must be entirely within the HAZ and located
as close as possible to the fusion boundary (between the weld metal and HAZ).

Figure 26—Hardness Locations for Partial Thickness Repair at Fusion Line
10.3.7.4.3 Requirements
The minimum average value and minimum individual value of impact energy for each set of three specimens when
tested at the minimum design temperature shall not be less than the minimum values specified for qualification of the
production weld or as otherwise specified by the company.

10.4 Repair Welder Qualification
10.4.1 General
The repair weld shall be made by a qualified welder experienced in methods used for repair of a defective weld. The
welder shall be qualified according to the requirements of 6.2 or 6.3 in addition to the requirements of this section.
When a repair procedure is required by 10.2, a welder shall be qualified using the applicable qualified repair
procedure. Welders shall be qualified using a completed weld to make a repair weld following all the details of the
repair procedure. The repair weld shall be deposited in the fixed position on a segment of a full-circumference test
weld for each repair type to be qualified in the location(s) specified by the company. The repair weld shall be a
minimum of 8 in. (203 mm) in length to provide the necessary weld deposit for destructive testing. A single completed
weld may be used to qualify more than one type of repair.

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API STANDARD 1104

Table 6—Repair Weld Maximum Hardness Values, HV10 a
Weld Metal
Hardness Location

Heat-affected Zone

Root and
Midthickness

Cap

Root and
Midthickness

Cap

Sour service, any welding
process

Note b

Note b

Note b

Note b

Non-sour service, any
welding process

275 c

275

275

325

Non-sour service, lowhydrogen welding process

275

275

350

350

NOTE

The company may specify other maximum hardness values.

a

A lower load may be used for t he narrow heat-affected zones in some welds made by mechanized or automatic processes.

b

For sour service, see applicable governing standard or specification document.

c

300 HV10 material 0.375 in. (9.5 mm) thick and above.

Details of the repair welder qualification shall be recorded and maintained with the complete results of the qualification
test for each type and location of repair to meet the requirements of 6.8.
10.4.2 Testing of Repairs
For a repair welder qualification test weld, the repair weld shall meet the visual examination requirements of 6.4 and
10.3.7.2.
The destructive testing requirements in 6.5 are for qualification of a repair welder, except that test specimens shall be
cut from the joint at each individual repair area location for each type of repair. The total number of specimens and the
test to which each shall be submitted are shown in Table 7. As noted in Table 7, when wall thickness is over 0.500 in.
(12.7 mm), the side bend tests shall be substituted for face bend or root bend tests.
Table 7—Type and Number of Butt Weld Test Specimens per Repair Type for Repair Welder Qualification
Repair Type

Tensile
Strength

Nick Break b

Root Bend

Face Bend

Side Bend

Total
(Minimum)

Full thickness

0

2

1a

1a

0

4

Internal partial
thickness

0

2

1a

0

0

3

External partial
thickness

0

2

0

1a

0

3

Cover pass

0

2

0

1a

0

3

Back weld

0

2

1a

0

0

3

a

Side bend tests are substituted for face bend or root bend tests when wall thickness is over 0.500 in. (12.7 mm).

b

One nick break specimen is taken at the transition between the repair weld end and original weld bead and the second nick break specimen
located at the midpoint of the repair weld deposit.

A welder who fails to pass the repair welder qualification test(s) shall be permitted to retest as described in 6.7.

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10.4.3 Qualification Limits
A repair welder who has successfully completed the qualification test described in 10.4.3 shall be qualified within the
limits of the essential variables described below. If any of the following essential variables are changed, the repair
welder using a repair procedure shall be requalified:
a) any change from one repair type to another, except when changing from a full thickness repair to any partial
thickness repair;
b) a change in filler metal group (see Table 1);
c) an increase in depth of the repair area greater than two times the deposited repair weld thickness in the repair
welder qualification test;
d) a change in position from that for which the repair welder has already qualified (e.g. a change from flat to vertical
or a change from vertical to horizontal or vice versa), except overhead position qualifies for all positions.

10.5 Supervision
The repair shall be made under the supervision of an individual acceptable to the company who is experienced and
knowledgeable in methods and procedures used for repairs.
Inspection of repairs shall be performed as specified by the company. Welding inspection personnel shall meet the
requirements of 8.3.
Repairs shall be documented and maintained by the company.

10.6 Acceptance Criteria
Repaired areas shall be inspected and evaluated by the same NDT methods previously used to determine a defect.
Visual inspection is considered adequate when the defect was rejected by visual means and repaired by grinding
without additional welding. NDT of a repair weld includes as a minimum the total repair area plus 10 % of the total
repair weld length, or 2 in. (50 mm); whichever is longer on each side of the repair area. Repairs shall be considered
acceptable when the repair area meets the standards of acceptability of Section 9 or more stringent acceptance
criteria specified by the company.
NOTE
A repair weld of a weld originally inspected and rejected using alternative acceptance criteria derived in accordance with
Annex A must be reinspected and meet the standards of acceptability of Section 9 or more stringent acceptance criteria as
specified by the company. Repair of the total length of defect(s) rejected by Annex A alternative acceptance criteria is required. A
partial length repair of a defect is prohibited.

11 Procedures for Nondestructive Testing (NDT)
11.1 Radiographic Test Methods
11.1.1 General
Section 11.1 presents the requirements for producing radiographic images on film or other media through the use of Xrays or gamma rays. A detailed procedure for the production of images shall be established and recorded. Radiographic
film produced by the use of this procedure shall have the density (see 11.1.10), clarity, and contrast required by this
standard. Images produced by other systems shall have the requisite sensitivity to define clearly the essential wire
diameter of the proper image quality indicator (IQI). The following criteria shall be used to evaluate images:
a) an acceptable image quality that is free from fog and from processing irregularities that could mask the image of
actual imperfections,

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API STANDARD 1104

b) the prescribed IQI and the essential wire diameter,
c) a satisfactory identification system,
d) an acceptable technique and setup,
e) compatibility with acceptance standards.
All requirements that refer to the quality of the resulting images shall apply equally to X-rays and gamma rays. The
use of radiographic testing and the frequency of its use shall be at the option of the company.
The company and the radiographic contractor should agree on the radiographic procedure or procedures to be used
prior to the performance of production radiography. The company shall require the contractor to demonstrate that the
proposed procedures produce acceptable images and shall require the contractor to use such procedures for
production radiography.
11.1.2 Details of Procedure
11.1.2.1 General
The details of each radiographic procedure shall be recorded. A copy of the record shall be furnished to the company
for its records. The record may be in the form of writing, a sketch, or both. As a minimum, each procedure shall
include the applicable details listed in 11.1.2.2 and 11.1.2.3.
11.1.2.2 Film Radiography
As a minimum, the procedure for film radiography shall include the following details.
a) Radiation source—The type of radiation source, the size of the effective source or focal spot, and the voltage
rating of the X-ray equipment.
b) Intensifying screens—The type and placement of the screens and, if lead is used, their thickness.
c) Film—The film brand or type or both and the number of film in the holder or cassette. For multiple-film techniques,
the way in which the film is to be viewed shall be specified.
d) Exposure geometry—Whether single-wall exposure for single-wall viewing (SWE/SWV), double-wall exposure for
single-wall viewing (DWE/SWV), or double-wall exposure for double-wall viewing (DWE/DWV); the distance from
the source or focal spot to the film; the relative positions of the film, weld, source, IQIs, and interval or reference
markers; and the number of exposures required for radiography of a complete weld.
e) Exposure conditions—Whether milliampere or curie minutes, the X-ray voltage or the input voltage and
amperage, and the exposure time.
f) Processing—Whether automatic or manual; the time and temperature for development and the time for stop bath
or rinsing, fixing, and washing; and drying details.
g) Materials—The type and thickness range of material for which the procedure is suitable.
h) IQIs—The type of material, identifying ASTM or ISO set, and essential wire diameter.
i) Heat shields—Material, thickness, and the distance from the film side of the heat shield to the pipe surface.

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11.1.2.3 Other Imaging Media
As a minimum, the procedure for radiography using imaging media other than film shall include the following details.
a) Radiation source—The type of radiation source, the size of the effective source or focal spot, and the voltage
rating of the X-ray equipment.
b) The image collection system used.
c) The image processing system used.
d) The image viewing system used.
e) The image storage system used.
f) Exposure geometry—Whether SWE/SWV, DWE/SWV, or DWE/DWV; whether in motion or still imaging; the
scanning speed for in motion imaging; the distance from the source or focal spot to the imager surface; the relative
positions of the imager surface, weld, source, IQIs, and the intervals or reference markers; the amount of
geometric magnification; the total magnification used for viewing; and the number of images required for
radiography of a complete weld.
g) Exposure conditions—Whether milliampere or curie minutes, the X-ray voltage or the input voltage and
amperage, and when applicable, the exposure time.
h) Materials—The type and thickness range of material for which the procedure is suitable.
i) IQIs—The type of material, identifying ASTM or ISO set, and essential wire diameter.
j) Heat shields—Material, thickness, and the distance from the imaging side of the heat shield to the pipe surface.
11.1.3 Exposure Geometry
11.1.3.1 Film Radiography
When a radiographic source is centered in the pipe for exposing a butt weld, one exposure is adequate for the
radiographic testing of the complete weld (SWE/SWV). When the radiographic source is outside but not more than 1/2 in.
(13 mm) from the weld surface, at least three exposures separated by 120° shall be made for the radiographic testing of
a complete weld (DWE/SWV). When the radiographic source is outside and more than 1/2 in. (13 mm) from the weld
surface, at least four exposures separated by 90° shall be made for the radiographic testing of a complete weld (DWE/
SWV). When the OD of the piping containing the weld is 3.500 in. (88.9 mm) or less, a DWE/DWV procedure may be
used. When this procedure is used and the radiation beam is offset so that the source-side and film-side portions of the
weld do not overlap in the areas of the radiograph being evaluated, at least two exposures separated by 90° shall be
made for the radiographic testing of a complete weld. When the source-side and film-side portions of the weld are
superimposed, at least three exposures separated by 60° shall be made for the radiographic testing of a complete weld.
When smaller diameter, thicker wall pipe is radiographed, additional exposures should be made to minimize the
distortion of imperfection images at the ends of the radiographs.
The minimum distance between the source or focal spot and the source side of the object being radiographed shall
be determined by the following formula (using constant units of measurement):
D = St ⁄ k

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API STANDARD 1104

where
D

is the minimum distance, in inches (mm), between the source or focal spot and the source side of the object
being radiographed;

S

is the size, in inches (mm), of the effective source or focal spot;

t

is the thickness of the weld, in inches (mm), including reinforcement, plus the distance between the film side
of the weld and the film;

k

is the geometric unsharpness factor.

When t is determined for SWE/SWV and DWE/SWV procedures, the thickness of the single wall and its weld
reinforcement shall be used. When t is determined for DWE/DWV procedures, the OD of the weld (i.e. the OD of the
pipe plus twice the average height of the weld crown) shall be used; k is defined as 0.02 in. (0.5 mm) for material with
a thickness of less than or equal to 2.000 in. (50.8 mm).
11.1.3.2 Other Imaging Media
For in-motion imaging, the exposure geometry shall be evaluated at the maximum scanning speed to be used during
the radiographic testing of the complete weld.
11.1.4 Type of IQIs
IQIs shall conform to the requirements of either ASTM E747 or ISO 19232-1 wire IQI. The company shall define
which type of IQI (ASTM or ISO) is to be used. The IQI shall be made of a material that is radiographically similar to
the material being welded.
11.1.5 Selection of IQIs
The IQI shall consist of either a series of six (6) wires for ASTM E747 wire type or a series of seven (7) wires for ISO
19232-1 wire type IQI, arranged in order of increasing diameter. The essential wire diameter to be used, based on the
thickness of the weld is shown in Table 8 for ASTM E747 wire type IQI and Table 9 for ISO 19232-1 wire type IQI. At
the option of the company, smaller wire diameter IQI than those specified above may be used, provided the required
radiographic sensitivity is obtained. The radiographic images of the IQI identifying style number and ASTM set letter
or ISO designation shall appear clearly. The image of the essential wire diameter shall appear clearly across the
entire area of interest.
NOTE
For purposes of IQI selection, when the SWE/SWV or DWE/SWV technique is used, the thickness of the weld means
specified wall thickness plus the weld reinforcement (internal plus external combined). When the "elliptical" DWE/DWV technique
is used, the thickness of the weld means twice the specified wall thickness plus the single weld reinforcement (internal plus
external combined). When the “superimposed” DWE/DWV technique is used, the thickness of the weld means twice the specified
wall thickness plus twice the weld reinforcement (internal plus external combined).

Table 8—Weld Thickness vs Diameter of ASTM E747 Wire Type IQI
Weld Thickness

Essential Wire Diameter

ASTM Set Letter

in.

mm

in.

mm

0 to 0.250

0 to 6.4

0.008

0.20

A

>0.250 to 0.375

>6.4 to 9.5

0.010

0.25

A or B

>0.375 to 0.500

>9.5 to 12.7

0.013

0.33

B

>0.500 to 0.750

>12.7 to 19.1

0.016

0.41

B

>0.750 to 1.000

>19.1 to 25.4

0.020

0.51

B

>1.000 to 2.000

>25.4 to 50.8

0.025

0.64

B

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Table 9—Weld Thickness vs Diameter of ISO Wire Type IQI
Weld Thickness

Essential Wire Diameter

Wire Identity

in.

mm

in.

mm

0 to 0.250

0 to 6.4

0.008

0.20

13

>0.250 to 0.375

>6.4 to 9.5

0.010

0.25

12

>0.375 to 0.500

>9.5 to 12.7

0.013

0.33

11

>0.500 to 0.750

>12.7 to 19.1

0.016

0.41

10

>0.750 to 1.000

>19.1 to 25.4

0.020

0.51

9

>1.000 to 2.000

>25.4 to 50.8

0.025

0.64

8

11.1.6 Placement of IQIs
11.1.6.1 Film
The IQIs shall be placed as follows.
a) When a complete weld is radiographed in a single exposure using a source inside the piping, at least four IQIs
placed across the weld and spaced approximately equally around the circumference shall be used. For the DWE/
DWV procedure, one IQI shall be placed on the source side of the pipe and across the weld so that the essential
wire image is superimposed onto the weld images. For the DWE/SWV or SWE/SWV procedures requiring
multiple exposures or multiple films for complete inspection of the weld, and where the length of film to be
interpreted is greater than 5 in. (130 mm), two IQIs placed across the weld and located on the film side shall be
used. One shall be within 1 in. (25 mm) of the end of the film length to be interpreted and the other shall be at the
center of the film. When the film length to be interpreted is 5 in. (130 mm) or less, one IQI shall be placed on the
film side, across the weld and located at the center of the length to be interpreted. When a repaired weld is
radiographed, an additional IQI shall be placed across each repaired area.
b) When it is not practical to place an IQI on the weld due to weld configuration or size, the IQI may be placed on a
separate block. Separate blocks shall be made of the same or radiographically similar material and may be used
to facilitate IQI positioning. The thickness of the separate block material should be the same as the thickness of
the weld.
c) Heat shields—IQI may be placed on a heat shield rather than in contact with the pipe, provided that the
acceptability of such IQI placement is demonstrated during procedure qualification.
11.1.6.2 Other Imaging Media
For imaging media other than film, IQI placement shall be the same as that required by 11.1.6.1. The IQI may be
placed above the surface of the pipe or held in position between the surface of the pipe and the imager by a fixture
attached to the imager or scanning device. Acceptability of such IQI placement shall be demonstrated during
procedure qualification.
11.1.7 Production Radiography
Only Level II or III radiographers shall interpret the radiographic images of production welds. Radiographers shall
report to the company all defects observed in the images unless the company requires that all imperfections observed
be reported. The radiographer shall indicate whether the weld meets the requirements of Section 9. The company
shall determine the final disposition of the weld.

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API STANDARD 1104

11.1.8 Identification of Images
Images shall be clearly identified by the use of lead numbers, lead letters, markers, or other identification so that the
proper weld and any imperfections in it can be quickly and accurately located. The company may specify the
identification procedure to be used. Whenever more than one image is used to inspect a weld, identification markers
shall appear on each image and adjacent images shall overlap. The last reference marker on each end of the image
shall appear on the appropriate adjacent images in a way that establishes that no part of the weld has been omitted.
11.1.9 Storage of Film and Other Imaging Media
11.1.9.1 Film
All unexposed films shall be stored in a clean, dry place where the conditions will not detrimentally affect the
emulsion. If any question arises about the condition of the unexposed film, sheets from the front and back of each
package or a length of film equal to the circumference of each original roll shall be processed in the normal manner
without exposure to light or radiation. If the processed film shows fog, the entire box or roll from which the test film
was removed shall be discarded, unless additional tests prove that the remaining film in the box or roll is free from
preexposure fog exceeding 0.30 H&D transmitted density for transparent-based film or 0.05 H&D reflected density for
opaque-based film.
NOTE
H&D refers to the Hurter-Driffield method of defining quantitative blackening of the film. (Ferdinand Hurter and Vero
Charles Driffield, “Photochemical Investigations and a New Method of Determination of the Sensitiveness of Photographic Plates,”
J. Soc. Chem. Ind., May 31, 1890.)

11.1.9.2 Other Imaging Media
Imaging media other than film shall be stored in strict accordance with the manufacturer’s recommendations.
11.1.10 Film Density
11.1.10.1 General
Except for small localized areas caused by irregular weld configurations, the transmitted H&D density in the area of
interest of transparent-based film shall not be less than 1.8 or greater than 4.0. The reflected H&D density for opaquebased film shall not be less than 0.5 nor greater than 1.5. Transmitted H&D densities through small localized areas
may exceed these limits; however, minimum densities shall not be less than 1.5 and maximum densities shall not
exceed 4.2; reflected H&D density shall not be less than 0.25 and shall not exceed 1.8.
NOTE
H&D refers to the Hurter-Driffield method of defining quantitative blackening of the film. (Ferdinand Hurter and Vero
Charles Driffield, “Photochemical Investigations and a New Method of Determination of the Sensitiveness of Photographic Plates,”
J. Soc. Chem. Ind., May 31, 1890.)

11.1.10.2 Film Viewing Equipment
The viewing equipment (illuminator) shall be of the variable high intensity type and shall be capable of viewing film
densities within the range specified in 11.1.10.1. It shall be equipped to prevent light, coming from around the outer
edge of the radiograph or through low density portions of the radiograph, from interfering with interpretations.
11.1.10.3 Film Viewing Facilities
Viewing facilities shall provide subdued background lighting of an intensity that will not cause troublesome reflections,
shadows, or glare on the radiograph.

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11.1.10.4 Image Processing
When requested by the company, film or other imaging media shall be processed, handled, and stored so that the
images are interpretable for at least three years after they are produced.
11.1.10.5 Image Processing Area
The image processing area and all accessories shall be kept clean at all times.
11.1.10.6 Radiation Protection
The radiographer shall be responsible for the protection and monitoring of every person working with or near radiation
sources. The protection and monitoring shall comply with applicable federal, state, and local regulations.

11.2 Magnetic Particle Test Method
When magnetic particle testing is specified by the company, a detailed written procedure for magnetic particle testing
shall be established that meets the requirements of ASTM E709. The company and the NDT contractor should agree
on the magnetic particle testing procedure or procedures prior to the performance of production testing.
The company shall require the contractor to demonstrate that the proposed procedures will produce acceptable
results and shall require the contractor to use such procedures for production testing.

11.3 Liquid Penetrant Test Method
When liquid penetrant testing is specified by the company, a detailed written procedure for liquid penetrant testing
shall be established that meets the requirements of ASTM E165. The company and the NDT contractor should agree
on the liquid penetrant testing procedure or procedures prior to the performance of production testing.
The company shall require the contractor to demonstrate that the proposed procedures will produce acceptable
results and shall require the contractor to use such procedures for production testing.

11.4 Ultrasonic Test Methods
11.4.1 General
When ultrasonic testing is specified by the company for the inspection of new and/or in-service circumferential butt
welds, the requirements of this section shall apply. A detailed procedure for use of the individual ultrasonic techniques
shall be established and recorded. The use of ultrasonic testing and the scope of its use shall be at the option of the
company.
The company and the ultrasonic contractor should agree on the ultrasonic procedures before the performance of
production testing. The company shall require the ultrasonic contractor to demonstrate the proposed procedures to
produce acceptable and accurate results and shall require the contractor to use such procedures for production
testing.
Caution is advised when this method is applied to in-service weld inspection due to potential parent material and
surface imperfections that can interfere with the use of the ultrasonic technique.
All surfaces to be ultrasonically scanned shall be in the uncoated condition. For new construction projects, the coating
cutback (bare pipe length) at pipe ends necessary for ultrasonic scanning should be specified prior to the pipe being
coated. Pipe seams should be ground flush with the pipe surface for the distance necessary for ultrasonic scanning.

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API STANDARD 1104

11.4.2 Details of Procedure
11.4.2.1 General
The details of each ultrasonic procedure shall be recorded. A copy of the record shall be furnished to the company for
its records. The record shall be in the form of both writing and sketches. As a minimum, each procedure shall include
the applicable details listed in 11.4.2.2.
11.4.2.2 Ultrasonic Procedure
As a minimum the procedure for ultrasonic testing of welds shall include the following specific application details.
a) Type of welds to be tested, joint preparation dimensions, and welding processes.
b) Material type (i.e. size, grade, thickness, process of manufacturing per API 5L).
c) Scanning surface preparation/condition.
d) Stage at which examination is to be performed.
e) Ultrasonic instrument/system and probes (i.e. manufacturer, type, size, etc.).
f) Automatic or manual.
g) Couplant.
h) Testing technique:
1) angles,
2) frequencies (MHz),
3) temperatures and ranges,
4) scanning patterns and speeds,
5) reference datum and location markers (i.e. root face and circumferential locations).
i) Reference standards—detail sketches showing plan view and cross-section view dimensions of production
material reference standard blocks and all reference reflectors.
j) Calibration requirements—the interval at which calibration of the instrument or system is required, the sequence
of setup calibration prior to inspecting welds, including all standard calibration blocks to be used, the reference
sensitivity reflectors to be used, the reference sensitivity-level setting [i.e. distance amplitude correction (DAC) or
time-corrected gain (TCG)], and the intervals for verification of calibration settings.
k) Scanning level—the sensitivity setting in decibels (dB) to be added to the reference sensitivity for scanning.
l) Evaluation level—the level or height of echoes detected during scanning at which further evaluation is required
and any sensitivity adjustment to be made before evaluating for acceptance or rejection.
m) Recording of results—type of record (e.g. sketch, thermal printer, compact disc, etc.) and whether all reflectors or
only unacceptable reflectors will be recorded.
n) Ultrasonic examination report—an example of the examination reports.