ASME Section VIII Div 1. design training
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About This Presentation
Guide for studying ASME U stamp vessel design as per ASME Sec. VIII Div. 1.
Slide Content
Welcome to
Training Program on GUIDED TOUR OF ASME Training Program on GUIDED TOUR OF ASME
CODESCODES
Presented byPresented by
P. S. KULKARNIP. S. KULKARNI
Training Program on GUIDED TOUR OF ASME Training Program on GUIDED TOUR OF ASME
CODESCODES
Presented byPresented by
P. S. KULKARNIP. S. KULKARNI
Agenda - session 1Agenda - session 1
•This session will provide:
–An introduction to Codes and
Standards
–Objectives of Codes/ Standards.
–ASME Code System.
–Introduction To ASME Sec. VIII-1
•Approximate duration – 8.0 Hours
•This session will provide:
–An introduction to Codes and
Standards
–Objectives of Codes/ Standards.
–ASME Code System.
–Introduction To ASME Sec. VIII-1
•Approximate duration – 8.0 Hours
CODE
Credibility
Collective Knowledge
and Experience
2 S
Safety
(Plant, Personnel, People)
Standardization
2 C
WHY ADOPT CODES ?
Credibility
Collective Knowledge
and Experience
2 S
Safety
(Plant, Personnel, People)
Standardization
2 C
WHY ADOPT CODES ?
Common pressure vessel codes
• ASME Sec VIII Div 1 and Div 2
• BS 5500
• IS 2825
• Ad Merk Blatter (German)
• AFNOR (French)
• ASME Sec VIII Div 1 and Div 2
• BS 5500
• IS 2825
• Ad Merk Blatter (German)
• AFNOR (French)
ASME Codes
Issue freq. : New edition every 3 years, on 1
st
July
latest edition was on 1st July 04.
Addenda : In-between revisions, issued yearly
also on 1st July.
2004 Edn. & '04 add. --- 1st July '04
2005 Addenda --- 1st July '05
2006 Addenda --- 1st July '06
Again new edition - 2007 (1st July)
Applicability : Edition & Addendas effective 6 months from date of issue
(i.e. 1
st
Jan of next year)
Issued by : American society of mechanical Engineers, New
York.
Issue freq. : New edition every 3 years, on 1
st
July
latest edition was on 1st July 04.
Addenda : In-between revisions, issued yearly
also on 1st July.
2004 Edn. & '04 add. --- 1st July '04
2005 Addenda --- 1st July '05
2006 Addenda --- 1st July '06
Again new edition - 2007 (1st July)
Applicability : Edition & Addendas effective 6 months from date of issue
(i.e. 1
st
Jan of next year)
Issued by : American society of mechanical Engineers, New
York.
ASME SEC. VIII DIV. 1
Pressure vessels within scope:
• Vessels having inside diameter above 6 in.
•Vessels designed for pressures above 15 psig and not
exceeding 3000 psi.
• Unfired steam boilers, evaporators,
Heat exchangers
Pressure vessels within scope:
• Vessels having inside diameter above 6 in.
•Vessels designed for pressures above 15 psig and not
exceeding 3000 psi.
• Unfired steam boilers, evaporators,
Heat exchangers
ASME Sec. VIII div.1--Excluded from scope
• Piping system & components beyond
battery limits.
• Vessels covered by other sections
• Vessels for human occupancy
• Pressure containers which are integral
part of rotating machinery.
• Piping system & components beyond
battery limits.
• Vessels covered by other sections
• Vessels for human occupancy
• Pressure containers which are integral
part of rotating machinery.
ASME Boiler & Pressure Vessel Codes
ASME Codes give stipulations and guidelines for the design,
materials, manufacture and testing of pressure vessels. These are
issued by the American Society of Mechanical Engineers, New York.
The codes were first issued in 1915. Since then, many changes have
been made and new sections added to the code as need arose. It is
a LIVE code and is revised and updated periodically. It keeps pace
with time and is responsive to its users.
ASME Codes give stipulations and guidelines for the design,
materials, manufacture and testing of pressure vessels. These are
issued by the American Society of Mechanical Engineers, New York.
The codes were first issued in 1915. Since then, many changes have
been made and new sections added to the code as need arose. It is
a LIVE code and is revised and updated periodically. It keeps pace
with time and is responsive to its users.
In its present from the ASME Code System is a follows
• Section I Power Boilers.
• Section II Material specifications.
Part A Ferrous materials,
Part B Non Ferrous Materials
Part C Welding rods, electrodes,
filler metals.
Part D Material properties.
CODE SYSTEM
• Section I Power Boilers.
• Section II Material specifications.
Part A Ferrous materials,
Part B Non Ferrous Materials
Part C Welding rods, electrodes,
filler metals.
Part D Material properties.
CODE SYSTEM
CODE SYSTEM
• Section III Nuclear Power Plant Components.
Section IV Heating Boilers.
• Section V Non destructive Examinations.
• Section VI Care and operation of Heating Boilers.
• Section VII Rules for care of Power Boilers.
• Section VIII Division 1 - Pressure Vessels
Division 2 Alternative Rules ( Pr. Vessel)
Division 3 Rules for constructive of High
Pressure Vessels.
• Section IX Welding and Brazing Qualifications.
• Section III Nuclear Power Plant Components.
Section IV Heating Boilers.
• Section V Non destructive Examinations.
• Section VI Care and operation of Heating Boilers.
• Section VII Rules for care of Power Boilers.
• Section VIII Division 1 - Pressure Vessels
Division 2 Alternative Rules ( Pr. Vessel)
Division 3 Rules for constructive of High
Pressure Vessels.
• Section IX Welding and Brazing Qualifications.
CODE SYSTEM, cont’d
Section XFiber glass reinforced Plastic Pressure
Vessels.
Section XIRules for in service inspection of Nuclear
Power Plant Components.
Section XFiber glass reinforced Plastic Pressure
Vessels.
Section XIRules for in service inspection of Nuclear
Power Plant Components.
APPLICABILITY
The editions and addenda become applicable after
six months from date of issue. Thus, 1
st
Jan. 2000,
the construction of Pressure Vessels shall be as per
1998 edition and 1999 addenda. However, for old
contracts spilling over beyond 1
st
Jan 2000, the old
applicable edition and addenda are valid.
The editions and addenda become applicable after
six months from date of issue. Thus, 1
st
Jan. 2000,
the construction of Pressure Vessels shall be as per
1998 edition and 1999 addenda. However, for old
contracts spilling over beyond 1
st
Jan 2000, the old
applicable edition and addenda are valid.
CODE INTERPRETATION
ASME issue written replies know as "Interpretations" to
the inquiries concerning technical aspects of the code
.These are issued twice in a year (July and December) and
are sent to "Edition - subscribers" as up-date service.
ASME issue written replies know as "Interpretations" to
the inquiries concerning technical aspects of the code
.These are issued twice in a year (July and December) and
are sent to "Edition - subscribers" as up-date service.
CODE CASES
Boiler and Pressure Vessels committee meets regularly to
consider
Proposed additions and revisions to the code. At the same
time it may formulate code cases to clarify ' Intent' of
existing requirements. These are published as code Case
books. It is published along with new editions and
supplements are automatically sent to subscribers of code
case book till new edition ispublished.
Boiler and Pressure Vessels committee meets regularly to
consider
Proposed additions and revisions to the code. At the same
time it may formulate code cases to clarify ' Intent' of
existing requirements. These are published as code Case
books. It is published along with new editions and
supplements are automatically sent to subscribers of code
case book till new edition ispublished.
ASME Sec. VIII Div. 1 has five different parts
Part 1 : UG – General requirements (Design requirements)
Part 2 : Material Specific Requirements
UCS – Carbon steel & low alloy steel
UHA – High alloy steels
UNF – Non ferrous metallurgy
Part 3 : Fabrication method specific requirements
UW – Welded construction
UF – Forging construction
Part 4 : Mandatory Appendices &
Part 5 : Non mandatory Appendices
Part 1 : UG – General requirements (Design requirements)
Part 2 : Material Specific Requirements
UCS – Carbon steel & low alloy steel
UHA – High alloy steels
UNF – Non ferrous metallurgy
Part 3 : Fabrication method specific requirements
UW – Welded construction
UF – Forging construction
Part 4 : Mandatory Appendices &
Part 5 : Non mandatory Appendices
Types of vesselsTypes of vessels
•Cylindrical – Horizontal or Vertical
•Spherical
•Cylindrical – Horizontal or Vertical
•Spherical
Steps in design -1Steps in design -1
•Find service conditions & metallurgy.
•Ensure ductility at service conditions
•Calculate thickness required (TR).
•Find service conditions & metallurgy.
•Ensure ductility at service conditions
•Calculate thickness required (TR).
Steps in design -2Steps in design -2
•Design thickness = TR + Corr Allow
•Roundup to commercially available thickness
to get nominal thickness
•Find MAWP from nominal thickness
•Design thickness = TR + Corr Allow
•Roundup to commercially available thickness
to get nominal thickness
•Find MAWP from nominal thickness
Solve a problem
Calculate the minimum thickness of a cylindrical shell of inside diameter
4000mm, tan to tan length of 8300mm and a design pr. of 100 Kg/sq cmg.
Design temperature of the vessel is 343 C
Material of construction – ASTM A 516 Gr 70
Allowable stress of vessel at 343 C = 16500 psi
Corrosion allowance = 3.0 mm
Efficiency of the weld joint – 1.0
Calculate the minimum thickness of a cylindrical shell of inside diameter
4000mm, tan to tan length of 8300mm and a design pr. of 100 Kg/sq cmg.
Design temperature of the vessel is 343 C
Material of construction – ASTM A 516 Gr 70
Allowable stress of vessel at 343 C = 16500 psi
Corrosion allowance = 3.0 mm
Efficiency of the weld joint – 1.0
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UW – 3 : WELD JOINTS CATEGORIES.
UW – 3 : WELD JOINTS CATEGORIES.
Category A :
1Longitudinal weld joints in main shell or nozzles.
2Any welded joints in spherical shell.
3.Any welded joints in Dished Head.
4.Circumferential Seam , Hemisph. head to shell.
Category A :
1Longitudinal weld joints in main shell or nozzles.
2Any welded joints in spherical shell.
3.Any welded joints in Dished Head.
4.Circumferential Seam , Hemisph. head to shell.
UW – 3 : WELD JOINTS CATEGORIES.
Category B :
1Circumferential seam in main shell, or nozzle
2Circumferential seam connecting formed head (other
than hemi-spherical head) to shell.
Category B :
1Circumferential seam in main shell, or nozzle
2Circumferential seam connecting formed head (other
than hemi-spherical head) to shell.
UW – 3 : WELD JOINTS CATEGORIES . Contd.
Category C :
• Weld joints connecting flanges, tube sheets, flat
head to main shell or Nozzles
(Flange Welds)
Category D:
• Welds joining communicating chamber or nozzle
to the main shell / heads.
(Attachment Welds).
Category C :
• Weld joints connecting flanges, tube sheets, flat
head to main shell or Nozzles
(Flange Welds)
Category D:
• Welds joining communicating chamber or nozzle
to the main shell / heads.
(Attachment Welds).
Types of endsTypes of ends
FLAT HEADS :
– For low pressures up to 5 kg/sqcm
FORMED HEADS :
–Torispherical
•Generally used up to 15 kg/sqcm
–Ellipsoidal
•Generally used between 15 to 25 kg/sqcm
–Hemispherical
•Generally used above 25 kg/sqcm.
CONICAL HEADS : for Special purposes.
FLAT HEADS :
– For low pressures up to 5 kg/sqcm
FORMED HEADS :
–Torispherical
•Generally used up to 15 kg/sqcm
–Ellipsoidal
•Generally used between 15 to 25 kg/sqcm
–Hemispherical
•Generally used above 25 kg/sqcm.
CONICAL HEADS : for Special purposes.
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For spherical shells / head :
t = P x R / (2SE - 0.2P) ….for Thickness
P = 2SEt / (R + 0.2t)….for MAWP
FORMED HEADS
For Torisph. Heads : (L = Crown Rad., r = 0.06 x L)
t, = 0.885 x P x L / (SE - 0.1P)… for Thickness
P = SEt / ( 0.885L + 0.1 t ) … for MAWP
For Ellipsoidal Heads : ( 2 : 1 type)
t = P x D / (2SE - 0.2P) ….for Thickness
P = 2SEt / (D + 0.2t) ….for MAWP
t = P x R / (2SE - 0.2P) ….for Thickness
P = 2SEt / (R + 0.2t)….for MAWP
FORMED HEADS
For Torisph. Heads : (L = Crown Rad., r = 0.06 x L)
t, = 0.885 x P x L / (SE - 0.1P)… for Thickness
P = SEt / ( 0.885L + 0.1 t ) … for MAWP
For Ellipsoidal Heads : ( 2 : 1 type)
t = P x D / (2SE - 0.2P) ….for Thickness
P = 2SEt / (D + 0.2t) ….for MAWP
UW-11 :RT and UT EXAMINATIONS
Full Radiography is required in following cases :
• All butt welds of vessels for lethal substances
• If thickness exceeds given in table UCS-57, UHA - 33,
• Butt welds of unfired boilers, with design pr. > 50 psi.
• For all other vessels, All cat. A welds full radiography .
Cat. B & C welds which intersect the Cat. A welds shall be
spot radiographed.
• Radiography is not required of category B and C butt
welds in nozzles less than NPS 10 or 1 1/8 in. thick.
Full Radiography is required in following cases :
• All butt welds of vessels for lethal substances
• If thickness exceeds given in table UCS-57, UHA - 33,
• Butt welds of unfired boilers, with design pr. > 50 psi.
• For all other vessels, All cat. A welds full radiography .
Cat. B & C welds which intersect the Cat. A welds shall be
spot radiographed.
• Radiography is not required of category B and C butt
welds in nozzles less than NPS 10 or 1 1/8 in. thick.
UW-11 :RT and UT EXAMINATIONS…contd.
1Spot Radiography : Spot RT of Butt joints if
design efficiency is selected for spot radiography.
2No Radiography : No RT of weld joints if design efficiency is
selected for no radiography or vessel is designed for external
pressure
3Ultrasonic examination : May be substituted for RT only for
the final closure seam of a pressure vessel.
1Spot Radiography : Spot RT of Butt joints if
design efficiency is selected for spot radiography.
2No Radiography : No RT of weld joints if design efficiency is
selected for no radiography or vessel is designed for external
pressure
3Ultrasonic examination : May be substituted for RT only for
the final closure seam of a pressure vessel.
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UW – 12 :WELDED JOINT TYPES
UW – 12 :WELDED JOINT EFFICIENCY
RT – 1 : Full Radiography ( E=1) :
Full length radiography of all butt welds
RT – 2 : Full Radiography ( E=1):
Cat – A: Full length radiography
Cat – B: Spot RT per [UW – 11 (a) 5 (b)]
RT – 3 : Spot radiography ( E= 0.85)
RT – 4 : No radiography ( E= 0.7)
RT – 1 : Full Radiography ( E=1) :
Full length radiography of all butt welds
RT – 2 : Full Radiography ( E=1):
Cat – A: Full length radiography
Cat – B: Spot RT per [UW – 11 (a) 5 (b)]
RT – 3 : Spot radiography ( E= 0.85)
RT – 4 : No radiography ( E= 0.7)
Some key points:Some key points:
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Out of roundness of Shell
Difference between the maximum and minimum inside diameter measured at
any cross section of the vessel shall not exceed 1% of the nominal diameter at
that cross section under consideration.
The diameter can be measured from either inside or outside. If measured from
outside shall be corrected for the thickness at that cross section.
Difference between the maximum and minimum inside diameter measured at
any cross section of the vessel shall not exceed 1% of the nominal diameter at
that cross section under consideration.
The diameter can be measured from either inside or outside. If measured from
outside shall be corrected for the thickness at that cross section.
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NOZZLE REINFORCEMENT
Required area of Reinforcement = d X t
r
d= Diameter of finished opening
t
r
= Required thickness of shell or head.
Reinforcement is waived off for single openings if:
1.finished opening size is 3 1/2" or less diameter in shell or head of
thickness 3/8" or less; or
2. finished opening size 2 3/8" or less diameter
in shell or head of thickness over 3/8";
Required area of Reinforcement = d X t
r
d= Diameter of finished opening
t
r
= Required thickness of shell or head.
Reinforcement is waived off for single openings if:
1.finished opening size is 3 1/2" or less diameter in shell or head of
thickness 3/8" or less; or
2. finished opening size 2 3/8" or less diameter
in shell or head of thickness over 3/8";
UCS-66 : IMPACT TESTING
1MDMT - Thickness point falls on or above the relevant
curve. Impact test is not required
(Curve UCS – 66 )
2Impact test is must, if MDMT < 120 deg F, and:
Thickness Of welded part > 4”
Thickness for Non-welded part > 6”
3Test normally required for MDMT < -55 deg. F
1MDMT - Thickness point falls on or above the relevant
curve. Impact test is not required
(Curve UCS – 66 )
2Impact test is must, if MDMT < 120 deg F, and:
Thickness Of welded part > 4”
Thickness for Non-welded part > 6”
3Test normally required for MDMT < -55 deg. F
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IMPACT TESTING EXEMPTION -- UG-20 (f) :
Impact test exempt for if,
Materials are P No 1, Gr. No. 1 and 2
1.Materials of curve A : thickness < 0.5 inch
2.Materials curve B, C, D : thickness < 1.0 inch
3.Hydrostatic test performed as required
4.Design temp = -20 deg F to 650deg.F
5.No cyclic or thermal shock loading
Impact test exempt for if,
Materials are P No 1, Gr. No. 1 and 2
1.Materials of curve A : thickness < 0.5 inch
2.Materials curve B, C, D : thickness < 1.0 inch
3.Hydrostatic test performed as required
4.Design temp = -20 deg F to 650deg.F
5.No cyclic or thermal shock loading
IMPACT TESTINGEXEMPTION…….contd.
1UCS-68 (c) : If PWHT is performed when not a Code
requirement, reduction of 30 deg. F (17
0
C) in impact testing
exemption temp.(from Fig UCS-66) may be given for P No. 1
materials
2If coincident ratio is < 1, Reduction to exemption temperature
may be given as per UCS-66.1
1UCS-68 (c) : If PWHT is performed when not a Code
requirement, reduction of 30 deg. F (17
0
C) in impact testing
exemption temp.(from Fig UCS-66) may be given for P No. 1
materials
2If coincident ratio is < 1, Reduction to exemption temperature
may be given as per UCS-66.1
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•PWHT temperature is higher of the two for dissimilar metal joints
UW-40 : POST-WELD HEAT TREATMENT
• PWHT is Code Requirement if thickness exceeds
those given in tables for respective materials .
• Furnace PWHT method is preferred .
• Min. Overlap for PWHT in multiple heats = 5 ft.
• Local PWHT : Min Soak Band = weld width + Lesser of
2’’ or t. and it shall extend full 360 deg for circ. Joint
UW-40 : POST-WELD HEAT TREATMENT
• PWHT is Code Requirement if thickness exceeds
those given in tables for respective materials .
• Furnace PWHT method is preferred .
• Min. Overlap for PWHT in multiple heats = 5 ft.
• Local PWHT : Min Soak Band = weld width + Lesser of
2’’ or t. and it shall extend full 360 deg for circ. Joint
· Still air cooling permitted below 800 deg .F.
UCS-56: POST-WELD HEAT TREATMENT
· Max. Loading temp in furnace = 800 deg .F
· Max. heating rate 400 deg F/hr/inch of thickness.
· Soaking period as per UCS-56 tables.
· Temp difference between hottest and coldest
parts of vessel shall not exceed 150 deg .F
· Max. cooling rate = 500 deg .F /hr/inch of thk.
· Max. offloading temp = 800 deg. F
UCS-56: POST-WELD HEAT TREATMENT
· Max. Loading temp in furnace = 800 deg .F
· Max. heating rate 400 deg F/hr/inch of thickness.
· Soaking period as per UCS-56 tables.
· Temp difference between hottest and coldest
parts of vessel shall not exceed 150 deg .F
· Max. cooling rate = 500 deg .F /hr/inch of thk.
· Max. offloading temp = 800 deg. F
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Summary of NDT
NDE OF PRESSURE VESSELS
Selection of a particular NDT technique :
Applicable NDT methods / Welding Discontinuities
Discontinuities
Applicable NDT Methods
RT T PT MT VT ET
Porosity Ö * Ö
a *
b
Ö
a *
Slag Inclusion Ö Ö NA *
b
NA *
Incomplete fusion * Ö NA *
b
NA *
Incomplete Penetration Ö Ö NA * NA *
Undercut Ö * * * Ö *
Overlap
NA
* Ö Ö * *
Cracks * Ö Ö
a
Ö
b
Ö
a
Ö
Laminations
NA
Ö
Ö
a,c
Ö
b,c
Ö
a,c NA
Selection of a particular NDT technique :
Applicable NDT methods / Welding Discontinuities
Discontinuities
Applicable NDT Methods
RT T PT MT VT ET
Porosity Ö * Ö
a *
b
Ö
a *
Slag Inclusion Ö Ö NA *
b
NA *
Incomplete fusion * Ö NA *
b
NA *
Incomplete Penetration Ö Ö NA * NA *
Undercut Ö * * * Ö *
Overlap
NA
* Ö Ö * *
Cracks * Ö Ö
a
Ö
b
Ö
a
Ö
Laminations
NA
Ö
Ö
a,c
Ö
b,c
Ö
a,c NA
Applicable NDT methods for Weld joint types
Joints
NDT Methods
RT UT PT MT VT ET
Butt Ö Ö Ö Ö Ö Ö
Corner * Ö Ö Ö Ö *
T * Ö Ö Ö Ö *
Lap * * Ö Ö Ö *
Joints
NDT Methods
RT UT PT MT VT ET
Butt Ö Ö Ö Ö Ö Ö
Corner * Ö Ö Ö Ö *
T * Ö Ö Ö Ö *
Lap * * Ö Ö Ö *
Note to NDT Table
a.Surface
b.Surface and slightly subsurface
c.Weld preparation or edge of base metal
ÖApplicable method
*Marginal applicability depending on other factors.
a.Surface
b.Surface and slightly subsurface
c.Weld preparation or edge of base metal
ÖApplicable method
*Marginal applicability depending on other factors.
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UG-99 :HYDROSTATIC TEST
• Min. Inspection pressure = Test pressure / 1.3
• Hydrostatic Test pr. = 1.3 X MAWP X stress ratio
Stress ratio = Stress at test temp./Stress at design temp.
• Any non-hazardous liquid may be used for the test.
• Min. Test temp = MDMT + 30 deg. F ( 17 C )
• Inspection temperature <= 120 deg. F.
• The MAWP may be same as Design pr.
• Test gauge range = 1.5 to 4 times test pr.
• Min. Inspection pressure = Test pressure / 1.3
• Hydrostatic Test pr. = 1.3 X MAWP X stress ratio
Stress ratio = Stress at test temp./Stress at design temp.
• Any non-hazardous liquid may be used for the test.
• Min. Test temp = MDMT + 30 deg. F ( 17 C )
• Inspection temperature <= 120 deg. F.
• The MAWP may be same as Design pr.
• Test gauge range = 1.5 to 4 times test pr.
UG-100 :PNEUMATIC TESTS
• Pneumatic test is used instead of hydro when:
• Vessels cannot be safely filled with water
• Vessels in service in which traces of
testing liquid cannot be tolerated
• Test pr = 1.1 X MAWP X stress ratio.
• Test temp shall exceed MDMT by 30 deg F.
• Pr. Gauge range = 1.5 to 4 times test pressure
• Pneumatic test is used instead of hydro when:
• Vessels cannot be safely filled with water
• Vessels in service in which traces of
testing liquid cannot be tolerated
• Test pr = 1.1 X MAWP X stress ratio.
• Test temp shall exceed MDMT by 30 deg F.
• Pr. Gauge range = 1.5 to 4 times test pressure
Safety precautions for Pneumatic Test
• All welds around openings and attachment welds
with throat >= 6mm ( 0.25”) to be MT or PT tested
• The pr. shall be first raised to 50% of the test pr.
• The pressure then shall be reduced to a value of
test pressure /1.1 , to permit inspection.
• Then the pressure shall be raised in steps of
10% of test pr. To reach full test pressure
• All welds around openings and attachment welds
with throat >= 6mm ( 0.25”) to be MT or PT tested
• The pr. shall be first raised to 50% of the test pr.
• The pressure then shall be reduced to a value of
test pressure /1.1 , to permit inspection.
• Then the pressure shall be raised in steps of
10% of test pr. To reach full test pressure
CODE STAMPING
Each pressure vessel shall be marked with the following :
1)The official Code U Symbol or the official UM Symbol.
2) Name of the Manufacturer of the pressure vessel
preceded by the words "certified by";
3)Max. allowable working pressure ---- psi at ----
0
F.
4)Minimum design metal temperature ----
0
F ----psi
5)Manufacturer's serial number;
6)Year built.
Each pressure vessel shall be marked with the following :
1)The official Code U Symbol or the official UM Symbol.
2) Name of the Manufacturer of the pressure vessel
preceded by the words "certified by";
3)Max. allowable working pressure ---- psi at ----
0
F.
4)Minimum design metal temperature ----
0
F ----psi
5)Manufacturer's serial number;
6)Year built.
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