Asme Section I & VIII Fundamentals
Transcript of Asme Section I & VIII Fundamentals
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ASME Section I & Section VIIIFundamentals
Jurandir Primo, PE
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1.0 - INTRODUCTION:
The ASME Code design criteria consist of basic rules specifying the design method, design loadsallowable stress, acceptable materials, fabrication, testing, certification and inspection requirements.
The design method known as "design by rule" uses design pressure, allowable stress and a desigformula compatible with the geometry to calculate the minimum required thickness of pressurized tanks
vessels and pipes.
The ASME - American Society of Mechanical Engineers - International Boiler and Pressure VesseCode is made of12 sections and contains over15 divisions and subsections.
1.1 - Code Sections
I. Power BoilersII. MaterialsIII. Rules for Construction of Nuclear Facility ComponentsIV. Heating BoilersV. Nondestructive Examination
VI. Recommended Rules for the Care and Operation of Heating BoilersVII. Recommended Guidelines for the Care of Power BoilersVIII. Pressure VesselsIX. Welding and Brazing QualificationsX. Fiber-Reinforced Plastic Pressure VesselsXI. Rules for In-service Inspection of Nuclear Power Plant ComponentsXII. Rules for Construction and Continued Service of Transport Tanks
SECTION I. Power Boilers
This Section provides requirements for all methods of construction of power, electric, and miniaturboilers; high temperature water boilers used in stationary service; and power boilers used in locomotive
portable, and traction service.
SECTION II. Materials
Part A - Ferrous Material Specifications Part B - Nonferrous Material Specifications Part C - Specifications for Welding Rods, Electrodes, and Filler Metals Part D - Properties
SECTION III. Rules for Construction of Nuclear Facility Components
Subsection NCA - General Requirements for Divisions 1 and 2
DIVISION 1
Subsection NB- Class 1 Components Subsection NC- Class 2 Components Subsection ND- Class 3 Components Subsection NE- Class MC Components Subsection NF - Supports Subsection NG - Core Support Structures Subsection NH - Class 1 Components in Elevated Temperature Service
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DIVISION 2
Code for Concrete Containments
DIVISION 3
Containments for Transportation and Storage
SECTION IV. Heating Boilers
Requirements for design, fabrication, installation and inspection of steam generating boilers, and hot wateboilers intended for low pressure service that are directly fired by oil, gas, electricity, or coal. It containappendices which cover approval of new material, methods of checking safety valve, safety relief valvcapacity, definitions relating to boiler design and welding and quality control systems.
SECTION V. Nondestructive Examination
Requirements and methods for nondestructive examination which are referenced and required by othecode Sections. It also includes manufacturer's examination responsibilities, duties of authorized inspector
and requirements for qualification of personnel, inspection and examination.
SECTION VI. Recommended Rules for the Care and Operation of Heating Boilers
It defines general descriptions, terminology and guidelines applicable to steel and cast iron boilers limiteto the operating ranges of Section IV Heating Boilers. It includes guidelines for associated controls anautomatic fuel burning equipment.
SECTION VII. Recommended Guidelines for the Care of Power Boilers
Guidelines to promote safety in the use of stationary, portable, and traction type heating boilers. Thsection provides guidelines to assist operators of power boilers in maintaining their plants as safely a
possible. Contains fuels for routine operation; Operating and maintaining boiler appliances; Inspection anprevention of boiler failure; Design of installation; Operation of boiler auxiliaries; Control of internachemical conditions
SECTION VIII. Pressure Vessels
Division 1 - Provides requirements applicable to the design, fabrication, inspection, testing, ancertification of pressure vessels operating at either internal or external pressures exceeding 15 psig
Division 2 - Alternative rules, provides requirements to the design, fabrication, inspection, testing, ancertification of pressure vessels operating at either internal or external pressures exceeding 15 psig.
Division 3 - Alternative rules for Construction of High Pressure Vessels, provides requirements applicabto the design, fabrication, inspection, testing, and certification of pressure vessels operating at eitheinternal or external pressures generally above 10,000 psi.
SECTION IX. Welding and Brazing Qualifications
Rules relating to the qualification of welding and brazing procedures as required by other Code Sectionfor component manufacture. Covers rules are related to the qualification and re-qualification of welderand welding and brazing operators in order that they may perform welding or brazing as required by otheCode Sections in the manufacture of components.
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SECTION X. Fiber-Reinforced Plastic Pressure Vessels
Requirements for construction ofFRP (Fiber-Reinforced Plastic) pressure vessels in conformance with manufacturer's design report. It includes production, processing, fabrication, inspection and testinmethods required.
SECTION XI. Rules for In-service Inspection of Nuclear Power Plant Components
Requirements for the examination, in-service testing and inspection, and repair and replacement ocomponents and systems in light-water cooled and liquid-metal cooled nuclear power plants.
SECTION XII. Rules for Construction and Continued Service of Transport Tanks
Requirements for construction and continued service of pressure vessels for the transportation odangerous goods via highway, rail, air or water at pressures from full vacuum to 3,000 psig and volumegreater than 120 gallons.
1.2 - The ASME B31 Code
ASME B31 was earlier known as ANSI B31. The B31 Code for Pressure Piping, covers Power PipingFuel Gas Piping, Process Piping, Pipeline Transportation Systems for Liquid Hydrocarbons and OtheLiquids, Refrigeration Piping and Heat Transfer Components and Building Services Piping.
Piping consists of pipe, flanges, bolting, gaskets, valves, relief devices, fittings and the pressurcontaining parts of other piping components. It also includes hangers and supports, and other equipmenitems necessary to prevent overstressing the pressure containing parts. It does not include suppostructures such as frames of buildings, buildings stanchions or foundations.
B31.1 - 2001 - Power Piping
Required piping for industrial plants and marine applications. This code prescribes requirements for th
design, materials, fabrication, erection, test, and inspection of power and auxiliary service piping systemfor electric generation stations, industrial institutional plants, central and district heating plants.
The code covers boiler external piping for power boilers and high temperature, high pressure water boilerin which steam or vapor is generated at a pressure of more than 15 PSIG; and high temperature water igenerated at pressures exceeding 160 PSIG and/or temperatures exceeding 250 degrees F.
B31.2 - 1968 - Fuel Gas Piping
This has been withdrawn as a National Standard and replaced by ANSI/NFPA Z223.1, but B31.2 is stavailable from ASME and is a good reference for the design of gas piping systems (from the meter to thappliance).
B31.3 - 2002 - Process Piping
Code rules for design of chemical, petroleum plants, refineries, hydrocarbons, water and steam. ThiCode contains rules for piping typically found in petroleum refineries; chemical, pharmaceutical, textilepaper, semiconductor, and cryogenic plants; and related processing plants and terminals.
It prescribes requirements for materials and components, design, fabrication, assembly, erectionexamination, inspection, and testing of piping. Also included is piping which interconnects pieces or stagewithin a packaged equipment assembly.
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B31.4 - 2002 - Pipeline Transportation Systems for Liquid Hydrocarbons and Other Liquids
This Code prescribes requirements for the design, materials, construction, assembly, inspection, antesting of piping transporting liquids such as crude oil, condensate, natural gasoline, natural gas liquidsliquefied petroleum gas, carbon dioxide, liquid alcohol, liquid anhydrous ammonia and liquid petroleumproducts between producers' lease facilities, tank farms, natural gas processing plants, refineriesstations, ammonia plants, terminals (marine, rail and truck) and other delivery and receiving points.
The requirements for offshore pipelines are found in Chapter IX. Also included within the scope of thCode are:
Primary and associated auxiliary liquid petroleum and liquid anhydrous ammonia piping at pipelinterminals (marine, rail and truck), tank farms, pump stations, pressure reducing stations and meterinstations, including scraper traps, strainers, and proper loops; Storage and working tanks including pipe-type storage fabricated from pipe and fittings, and pipininterconnecting these facilities; Liquid petroleum and liquid anhydrous ammonia piping located on property which has been seaside for such piping within petroleum refinery, natural gasoline, gas processing, ammonia, and buplants;
Those aspects of operation and maintenance of liquid pipeline systems relating to the safety anprotection of the general public, operating company personnel, environment, property and the pipinsystems.
B31.5 - 2001 - Refrigeration Piping and Heat Transfer Components
This Code prescribes requirements for the materials, design, fabrication, assembly, erection, test, aninspection of refrigerant, heat transfer components, and secondary coolant piping for temperatures as lowas -320 F (-196 C), whether erected on the premises or factory assembled, except as specificalexcluded in the following paragraphs.
Users are advised that other piping Code Sections may provide requirements for refrigeration piping
their respective jurisdictions.
This Code shall not apply to: Any self- contained or unit systems subject to the requirements of Underwriters Laboratories oother nationally recognized testing laboratory: Water piping and piping designed for external or internal gage pressure not exceeding 15 psi (10kPa) regardless of size; or Pressure vessels, compressors, or pumps, but does include all connecting refrigerant ansecondary coolant piping starting at the first joint adjacent to such apparatus.
B31.8 - 2003 - Gas Transmission and Distribution Piping Systems
This Code covers the design, fabrication, installation, inspection, and testing of pipeline facilities used fothe transportation of gas. This Code also covers safety aspects of the operation and maintenance of thosfacilities.
B31.8S-2001 - 2002 - Managing System Integrity of Gas Pipelines
This Standard applies to on-shore pipeline systems constructed with ferrous materials and that transpogas. Pipeline system means all parts of physical facilities through which gas is transported, including pipevalves, appurtenances attached to pipe, compressor units, metering stations, regulator stations, deliverstations, holders and fabricated assemblies.
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The principles and processes are applicable to all pipeline systems. This Standard is specifically designeto provide the operator (as defined in section 13) with the information necessary to develop and implemenan effective integrity management program utilizing proven industry practices and processes.
The processes and approaches within this Standard are applicable to the entire pipeline system.
B31.9 - 1996 - Building Services Piping
This Code Section has rules for the piping in industrial, institutional, commercial and public buildings, anmulti-unit residences, which does not require the range of sizes, pressures, and temperatures covered iB31.1.
This Code prescribes requirements for the design, materials, fabrication, installation, inspectionexamination and testing of piping systems for building services. It includes piping systems in the buildinor within the property limits.
B31.11 - 2002 - Slurry Transportation Piping Systems
Rule for design, construction, inspection and security requirements of slurry piping systems. This cod
covers piping systems that transport aqueous slurries of no hazardous materials, such as coal, mineraores and other solids between a slurry processing plant and the receiving plant.
B31G - 1991 - Manual for Determining Remaining Strength of Corroded Pipelines
The scope of this Manual includes all pipelines within the scope of the pipeline codes that are part oASME B31 Code for Pressure Piping, ASME B31.4, Liquid Transportation Systems for HydrocarbonsLiquid Petroleum Gas, Anhydrous Ammonia, and Alcohols; ASME B31.8, Gas Transmission anDistribution Piping Systems; and ASME B31.11, Slurry Transportation Piping Systems. Parts 2, 3, and are based on material included in ASME Guide for Gas Transmission and Distribution Piping Systems1983 Edition.
1.3 - ASME Certification and Inspection Procedures:
The symbols "A", "S", "U", "PP" and "H" Stamps covers the fabrication and alteration ohigh pressure boilers, unfired pressure vessels, power piping and heating boilers.
Once any ASME Stamped Pressure Vessel is manufactured, it is checked, tested and approved by thASME Authorized Inspector, who review all the procedures and all the documentation and sign the DatReport Form before to procedure to Stamp the name plate with the U orUM symbols, which meanthat the Pressure Vessel fully complies with the ASME Code rules for construction of Pressure Vessels.
The National Board of Boiler & Pressure Vessel Inspectors uses the NB Symbol as well the RSymbol to repair or to alterany previous Stamped Pressure Vessel.
All material used in manufacture must be documented. All welders must be certified. Manufacturers havan Authorized Inspector, who is the judge of code acceptability. The quality ofweld is then checked folack ofweld penetration, slag inclusion, overlap and excessive reinforcement. At the final inspectiothe units are hydrostatically tested at 1.5 times working pressure and observed for leaks.
1.4 Imperial and Metric Values:
Professionals and students should be well versed in conversion practice. Many US customary unvalues presented in the ASME codes do not convert directly into metric values in the ASME editions.
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2.0 SECTION I & SECTION VIII Fundamentals:
The formulae in ASME Section I and Section VIII are used to determine the minimum required thicknesand design pressure of piping, tubes, drums and headers using the Maximum Allowable WorkinPressure(MAWP).
However, Paragraph UG-31 states, that these formulae may be also used for calculating wall thicknes
oftubes and pipes under internal pressure.
2.1 Design:
The ASME Boiler Code Section I, as well as Section VIII, requires longitudinal and circumferential bujoints to be examined by full radiograph.
When the vessel design is required fully radiographed longitudinal butt-welded joint, the cylindrical shewill have a joint efficiency factor (E) of 1.0. This factor corresponds to a safety factor (or materiquality factor) of3.5 in the parent metal.
When the vessel design is required non radiographed longitudinal butt-welded joints the vessel will hav
a joint efficiency factor (E) of 0.7, which corresponds to a safety factor of 0.5 in., resulting in aincrease of43% in the thickness of the plates.
2.2 Pressure Vessels Maximum Allowable Stress Values
The maximum allowable stress values to be used in the calculation of the vessels wall thickness are givein the ASME Code for many different materials. These stress values are a function of temperature.
Grade 55 13,800 18,300Grade 60 15,000 20,000
Grade 65 16,300 21,700
Grade 70 17,500 23,300
Grade A 11,300 15,000
Grade B 12,500 16,700
Grade C 13,800 18,300
SA - 36 12,700 16,900
Grade A 16,300 21,700
Grade B 17,500 23,300
Grade D 16,300 21,700
Grade E 17,500 23,300
Grade 304 11,200 20,000Grade 304L - 16,700
Grade 316 12,300 20,000
Grade 316L 10,200 16,700
Maximum Allowable Stress Value for Common Steels
Material Spec. Nbr Grade
DIVISION 1
-20F to
650F
DIVISION 2
-20F to
650F
Carbon Steel
Plates and
Sheets
High Alloy
Steel Plates
SA - 516
SA - 285
SA - 203
SA - 240
Division 1 governs the design by Rules, is less stringent from the standpoint of certain design details aninspection procedures, and thus incorporates a highersafety factor of 4. For example, if a 60,000 pstensile strength material is used, the Maximum Allowable Stress Value is 15,000 psi.
Division 2 governs the design by Analysis and incorporates a lower safety factor of 3. Thus, thmaximum allowable stress value for a 60,000 psi tensile strength material will become 20,000 psi.
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Many companies require that all their pressure vessels be constructed in accordance with Division because of the more exacting standards. Others find that they can purchase less expensive vesseby allowing manufacturers the choice of eitherDivision 1 or Division 2.
Normally, manufacturers will choose Division 1 for low-pressure vessels and Division 2 for highpressure vessels. The maximum allowable stress values at normal temperature range for the steel platemost commonly used in the fabrication of pressure vessels are given in Table above.
3.0 ASME SECTION I Power Boilers Types, Design, Fabrication, Inspection & Repair
Provides requirements for construction of power, electric, and miniature boilers; high temperature wateboilers used in stationary service; and power boilers used in locomotive, portable, and traction service.
Rules allow the use of the V, A, M, PP, S and E symbol stamps. The rules are applicable to boilers iwhich steam is generated at pressures exceeding 15 psig, and high temperature water boilers fooperation at pressures exceeding 160 psig and/or temperatures exceeding 250 F.
This code covers power boiler superheaters, economizers, and other pressure parts connectedirectly to the boiler without intervening valves are considered as part of the scope of Section 1.
3.1 SECTION I Boiler Tubes up to and including 5 inches O.D. (125 mm):
4. To calculate the minimum required thickness, according to paragraph PG-27.2.1, use equatiobelow:
b) To calculate the Maximum Allowable Working Pressure (MAWP):
Where:
t = Minimum Design Wall Thickness (in)P = Design Pressure (psi)D = Tube Outside Diameter (in)e = Thickness Factor (0.04 for expanded tubes; 0 = for strength welded tubes)S = Maximum Allowable Stress According to ASME Section II, Table 1A
Example 1 - Boiler Tube:
Calculate the minimum required wall thickness of a water tube boiler2.75 in O.D., strength welded (e = 0into place in a boiler. The tube has an average wall temperature of 650F. The Maximum AllowabWorking Pressure (MAWP) is 580 psi gauge. Material is carbon steel SA-192.
Note: Before starting calculations check the correct stress table in ASME Section II, Table 1A:
SA-192 = 11,800 psi allowable stress Div. 1.
Solution:
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For tubing up to and including 5 in O.D., use equation 1.1 above.P = [580 psi]D = [2.75 in]e = 0 (strength welded)S = [11,800 psi] at [650F])
t = 2.75 x 580 + 0.005 (2.75) + 0
2 (11,800) + 580
t = 0.079 in.
Note: Where the manufacturing process produces only standard plate thickness, so should be used 1/8 i(3.2 mm) minimum.
3.2 SECTION I Piping, Drums, and Headers:
The following formulae are found in ASME Section I, paragraph PG-27.2.2. The information for pipingdrums, or headers may be given with either the inside I or outside (D) measurement.
4. Using the outside diameter:
b) Using the inside radius:
Where:
t = Minimum Design Wall Thickness (in)P = Design Pressure (psi)D = Tube Outside Diameter (in)R = Tube Radius (in)E = Tube Welding Factor (1.0 for seamless pipe; 0.85 = for welded pipe)y = Wall Thickness Welding Factor (0.4 for 900F & lower; 0.7 for 950F & up)C = Corrosion Allowance (0 for no corrosion; 0.0625 in. commonly used; 0.125 in. maximum)S = Maximum Allowable Stress According to ASME Section II, Table 1A
Example 2 Steam Piping:
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Calculate the required minimum thickness of a seamless steam piping which carries steam at a pressurof900 psi gauge and a temperature of700F. The piping is 10.77 in O.D., (10 inches nominal) plain endthe material is SA-335 P1, alloy steel. Allow a manufacturers tolerance allowance of 12.5%.Note: Before starting calculations check the material stress table in ASME Section II, Table 1A:
SA-335 P1 = 13,800 psi allowable stress Div.1. Use equation 2.1:
P = [900 psi]D = [10.77 in]C = 0S = [13,800] (SA-335 P1 alloy steel at 700F)E = 1.0y = 0.4 (Ferritic steel less than 900F)
t = 900 x 10.77. + 0 =
2(13,800)(1.0) + 2(0.4)(900)
t = 0.34 in.
Therefore, including a manufacturers allowance of 12.5%; - 0.34 1.125 = 0.38 in.
Example 3 Maximum Allowable Working Pressure (MAWP):
Calculate the Maximum Allowable Working Pressure (MAWP) for a seamless steel pipe of material SA209-T1. The outside pipe diameter is 12.75 in. (nominal diam. 12 in.) with a wall thickness of 0.46 inThe operating temperature is 850F. The pipe is plain ended.
D = 12.75 in (outside diameter)t = 0.46 inC = 0 (3 to 4 inches nominal and larger)S = 13,100 psi (Section II, Table 1A, Div.1, SA-209-T1 at 850F)E = 1.0 (seamless pipe as per PG-9.1)y = 0.4 (austenitic steel at 850F)
Use equation 2.2:
P = 2SE (t C) =D (2y) (t C)
P = 2 (13,100) (1.0) x (0.46 0) =12.75 (2 x 0.4) (0.46 0)
P = 26,200 x 0.46 =12.75 0.368
P = 973 psi
Example 4 Welded Tube Boiler Drum:
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A welded water tube boiler drum ofSA-515-60 material is fabricated to an inside radius of 18.70 in. othe tube sheet and 19.68 in on the drum. The plate thickness of the tube sheet and drum are 2.34 inand 1.49 in., respectively.
The longitudinal joint efficiency is 100%, and the ligament efficiencies are 56% horizontal and 30%circumferential. The operating temperature is not to exceed 500F. Determine the Maximum AllowabWorking Pressure (MAWP) based on:
Welded Water Tube Boiler Drum:DRUM &
TUBESHEET
Note: This is a common example of a water tube drum fabricated from two plates of different thicknessThicker material is required where the boiler tubes enter the drum than is required for a plain drum.
This example has two parts:a) The drum consider the drum to be plain with no penetrations.b) The tube sheet consider the drum to have penetrations for boiler tubes.
(a) Drum. Use equation 2.4 (inside radius R):
Drum P=
SE(t - C)
R +(1 - y) (t- C)
Where:
S = 15,000 psi (Section II, Table 1A, Div.1, SA-515-60 at 500F)E = 1.0t = 1.49 inC = 0R = 19.68 iny = 0.4 (Ferritic steel less than 900F)
Drum P = (15,000) (1.0) (1.49 0).. =19.68 + (1 0.4) (1.49 0)
Drum P = 15,000 x 1.4919.68 + 0.894
Drum P = 1,086 psi
(b) Tube Sheet. Use equation 2.4 (inside radius R):
Where:
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S = 15,000 psiE = 0.56 (circumferential stress = 30% and longitudinal stress = 56%; therefore = 0.56 < 2 x 0.30)t = 2.34 inC = 0 (3 to 4 inches nominal and larger)R = 18.70 iny = 0.4 (Ferritic steel less than 900F)
Tube Sheet P = (15,000) (1.0) (2.34 0) =18.70 + (1 0.4) (2.34 0)
Tube Sheet P = 15,000 x 2.3418.70 + 1.404
Tube Sheet P = 1,746 psi
Note: Consider the Maximum Allowable Working Pressure (MAWP)= 1,086 psi (lowest number).
4.0 ASME SECTION VIII Division 1, Division 2, Division 3:
The ASME Section VIII, rules for fired or unfired pressure vessels, is divided into three divisions tprovide requirements applicable to the design, fabrication, inspection, testing, and certification. Thformulae and allowable stressespresented in this sketch are only forDivision 1, the main code.
It contains mandatory and non-mandatory appendices detailing supplementary design criterianondestructive examination and inspection acceptance standards. Rules pertaining to the use of the UUM and UV Code symbol stamps are also included.
4.1 SECTION VIII Thin Cylindrical Shells:
The formulae in ASME Section VIII, Division 1, paragraph UG-27, used for calculating the wathickness and design pressure of pressure vessels, are:
a) Circumferential Stress (longitudinal welds):
When, P < 0.385SE:
b) Longitudinal Stress (circumferential welds):
When, P < 1.25SE
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4.2 SECTION VIII Thick Cylindrical Shells:
For internal pressures higher than 3,000 psi, special considerations must be given as specified paragraph U-1 (d). As the ratio of t/R increases beyond 0.5, a more accurate equation is required tdetermine the thickness.
The formulae in ASME Appendix 1, Supplementary Design Formulas used for calculating thick wa
and design pressure, are:
a) For longitudinal stress (longitudinal welds):
When, P > 0.385SE:
and
b) For longitudinal stress (circumferential welds):
When, P > 1.25SE:
and
Where:
R = Design Radius (in.)Z = Dimensionless Factor
4.3 SECTION VIII Tube Spherical Shells:
The standard design method uses an increased wall thickness at the equator line of the vessel to suppothe additional stresses caused by the attachment of the legs. The formula for calculation the wall thicknesof a segmented plate of a sphere to be welded in a heat exchanger tube is:
t = PL+ C2SE 0.2P
L = Di/2
Where:
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t = Minimum Design Wall Thickness (in)P = Design Pressure (psi)Di = Inside Diameter of Sphere (in)L = Sphere Radius (in)E = Tube Welding Factor (1.0 for seamless pipe; 0.85 = for welded pipe)C = Corrosion Allowance (0 for no corrosion; 0.0625 in. commonly used; 0.125 in. maximum)S = Maximum Allowable Stress According to ASME Section II, Table 1A
Example 5 Thin Cylindrical Shells:
A vertical boiler is constructed ofSA-515-60 according to Section VIII-1. It has an inside diameter of96 inand an internal design pressure of 1,000 psi at 450 F. The corrosion allowance is 0.125 in., and joinefficiency is E = 0.85. Calculate the required thickness of the shell.
SA-515-60 = 15,000 psi allowable stress, ASME Section II, Table 1A, Div.1.
Since P < 0.385SE (6,545 psi) as 1,000 psi < 6,545 psi, use equation 1.3:
t = PR + C
SE 0.6P
Considering the external radius = (48 in. + 0.125 in.). Corrosion allowance = 0.125 in.
t = 1,000 x (48 in. + 0.125).. + 0.125 =2(15,000)(0.85) 0.6(1,000)
t = 0.0019 in.
Example 6 Thick Cylindrical Shells:
a) When P > 0.385SE:
Calculate the required shell thickness of an accumulator with P = 10,000 psi, R = 18 in., S = 20,000 psand E = 1.0. Assume a corrosion allowance of0.125 in.
ForP > 0.385SE (7,700 psi) as 10,000 psi > 7,700 psi, use equation 1.7:
t = R (Z
- 1) =
Z = (20,000)(1.0) + 10,000 = 30,000 = 3(20,000)(1.0) 10,000 10,000
t = (18) (3
1) + 0.125 = 8.08 in.
Example 7 Thick Cylindrical Shells:
b) When P < 0.385SE:
Calculate the required shell thickness of an accumulator with P = 7,650 psi, R = 18 in,S = 20,000 psandE = 1.0. Assume corrosion allowance = 0.
ForP< 0.385SE (7,700 psi) as 7,650 psi < 7,700 psi, use equation 1.3:
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t = PR + CSE 0.6P
t = 7,650 x 18 + 0(20,000)(1.0) 0.6(7,650)
t = 8.9 in.
Example 8 Comparison between Equation 1.3 and Equation 1.7:
Calculate the shell thickness, comparing the equation1.3 with another answer using equation 1.7.
t = R (Z
- 1) =
Z = (20,000)(1.0) + 7,650 = 27,650 = 2.24(20,000)(1.0) 7,650 12,350
t = (18 + 0) (2.24
- 1) =
t = 8.9 in.
This shows that the simple use of equation (1.3) is accurate over a wide range of R/t ratios.
5.0 SECTION I: Dished Heads Formulae:
Flanged and dished heads can be formed from carbon steel, stainless steel, and other ferrous and nonferrous metals and alloys. Flanged and dished heads can be formed in a size range from 4 in to 300 idiameter and in thickness range of14 Gauge to 1-1/2 thick.
Pressure vessel heads and dished ends are essentially the same the end caps of a pressure vessel tan
or an industrial boiler. They are supplied with a flanged edge to make it easier for the fabricatorto weld thhead to the main body of the tank.
Dished heads can be manufactured using a combination of processes, spinning & flanging, where thspherical radius is made via the spinning process and the knuckle is created under the flanging method.
5.1 Blank, Unstayed Dished Heads:
Paragraph PG-29.1 states that the thickness of a blank, unstayed dished head with the pressure on thconcave side, when it is a segment of a sphere, shall be calculated by the following formula:
Where:
t = Minimum thickness of head (in)P = maximum allowable working pressure (psi)L = Concave side radius (in)S = Maximum Allowable Working Stress (psi)
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Paragraph PG-29.2 states: The radius to which the head isdished shall be not greater than the outside diameter of theflanged portion of the head. Where two radii are used, thelonger shall be taken as the value ofLin the formula.
Example 9 Segment of a Spherical Dished Head:
Calculate the thickness of a seamless, blank unstayed dishedhead having pressure on the concave side. The head has aninsidediameter of 42.7 in. with a dish radius of 36.0 in. TheMaximum Allowable Working Pressure (MAWP) is 360 psi andthe material is SA-285 A. The temperature does not exceed 480F. State if this thickness meets Code.Solution: Use equation 1.11
P = 360 psi
L = 36.0 inS = 11,300 psi SA-285 A at 480F
t = 5 (360 x 36) =4.8 (11,300)
t = 1.19 in.
PG-29.6 states: No head, except a full-hemispherical head, shall be of a lesser thicknessthan thatrequired for a seamless shell of the same diameter. Then, the minimum thickness of piping is:
Where:
P = 360 psiD = 42.7 iny = 0.4 (Ferritic steel less than 900F)E = 1.0 (welded)
t = 360 x 42.7 =2(11,300)(1.0) + 2 (0.4)(360)
t = 0.67 in.
Therefore, the calculated head thickness meets the code requirements, since 1.19 > 0.67.
Example 10 - Segment of a Spherical Dished Head with a Flanged-in Manhole:
Calculate the thickness of a seamless, unstayed dished head with pressure on the concave side, having flanged-in manhole 6.0 in x 16 in. Diameter head is 47.5 in with a dish radius of45 in. The MAWP is 22psi, the material is SA-285-C, and temperature does not exceed 428F.
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First thing to check: is the radius of the dish at least 80% of the diameterof the shell?
Dish Radius = 45Shell Diameter 47.5
0.947 > 0.8 - The radius of the dish meets the criteria. Then, use equation 1.11:
P = 225 psiL = 45 inS = 13,800 psi (450F - use the next higher temperature).
t = 5 (225 x 45) =4.8 (13,800)
t = 0.764 in.
This thickness is for a blank head. PG-29.3 requires this thickness to be increased by 15%or 0.12in., whichever is greater. As 0.764 0.15 = 0.114in., that is less than 0.125 in., then, the thickness musbe increased by 0.125 in.
Then, the required head thickness is, t = 0.764 + 0.125 = ~0.90 in.
5.2 - Seamless or Full-Hemispherical Head:
The thickness of a blank, unstayed, full-hemispherical head with the pressure on the concave side shabe calculated by the following formula:
t = Minimum thickness of head (in)P = Maximum Allowable Working Pressure (psi)L = Radius to which the head was formed (in)S = Maximum Allowable Working Stress (psi)
The above formula shall not be used when the required thickness of the head given by the formulexceeds 35.6% of the inside radius. Instead, use the following formula:
Example 11 - Seamless or Full-Hemispherical Head:
Calculate the minimum required thickness for a blank, unstayed, full-hemispherical head. The radius twhich the head is dished is 7.5 in. The MAWP is 900 psi and the head material is SA 285-C. The averagtemperature of the header is 570F.
Solution: Use equation 1.13.
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P = 900 psiL = 7.5 in.S = 13,800 psi - (SA 285-C at 600F).
t = 900 x 7.5 =2 (13,800) 0.2 (900)
t = 0.24 in.
Check if this thickness exceeds 35.6% of the inside radius = 7.5 x 0.356 = 2.67 in. It does not excee35.6%, therefore the calculated thickness of the head meets the code requirements.6.0 - SECTION VIII-1: Dished Heads Formulae:
The Section VIII-1 determines the rules for dished heads. The most common configurations arspherical, hemispherical, elliptical (or ellipsoidal) and torispherical shapes.
How the shapes are, make some confusion for beginners and even professionals users of ASMVIII. To cast a little light on these subjects see the resume below:
Spherical or Hemispherical Heads
Semi-Elliptical Heads (2:1)
Elliptical or Ellipsoidal Heads (1.9:1)
Torispherical Heads
Flanged and Dished Heads
Flat Dished HeadsNon Standard 80-10 Dished Heads Dished Discs Toriconical Heads
6.1 - Spherical or Hemispherical Heads:
a) When t < 0.356R orP < 0.665SE:
and
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b) When t > 0.356R orP > 0.665SE:
and
Example 12 - Spherical or Hemispherical Head:
A pressure vessel is built ofSA-516-70 material and has an inside diameter of96 in. The internal desig
pressure is 100 psi at 450F. Corrosion allowance is 0.125 in. and joint efficiency is E =0.85. Calculatthe required thickness of the hemispherical head ifS is 20,000 psi?
Solution: Since 0.665SE > P = 11305 psi > 100 psi, use equation 2.1.
The inside radius in a corroded condition is equal to, R = 48 + 0.125 = 48.125 in.
t = PR =2SE 0.2P
t = 100 x 48.125 =2(20,000) (0.85) 0.2(100)
t = 0.14 in.
Example: Spherical Shell:
A spherical pressure vessel with an internal diameter of120 in has a head thickness of1 in. Determinthe design pressure if the allowable stress is 16300 psi. Assume joint efficiency E= 0.85. No corrosioallowance is stated to the design pressure.
Solution: Since t < 0.356R use equation 2.2.
P = 2SEt =
R + 0.2t
P = 2(16,300)(0.85)(1) =60 + 0.2(1)
P = 460 psi
The calculated pressure 460 psi is < 0.665SE (9213 psi); therefore, equation 2.2 is acceptable.
Example 13 - Thick Hemispherical Head:
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Calculate the required hemispherical head thickness of an accumulator with P = 10,000 psi, R = 18.0 inS = 15,000 psi, and E = 1.0. Corrosion allowance is 0.125 in.
Solution: As 0.665SE < P = 9975 psi < 10,000 psi, use equation 2.3.
Y = 2(15,000)(1.0) + 10,000 =2(15,000)(1.0) 10,000
Y = 40,000 = 220,000
t = R (Y1/3 1) = (18.0) (21/3 1) + 0,125 = 4.8 in.
6.2 Elliptical or Ellipsoidal Heads:
The commonly used semi-ellipsoidal head has a ratio of base radius to depth of2:1 (shown in Fig. 2aThe actual shape can be approximated by a spherical radius of 0.9D and a knuckle radius of 0.17DThe required thickness of2:1 heads with pressure on the concave side is given below:
Semi-Elliptical or Semi-Ellipsoidal Heads 2:1:
Example 14 - Elliptical or Ellipsoidal Heads:
Calculate the head thickness considering the dimensionsgiven below:
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Inside Diameter of Head (Di): 18.0 inInside Crown Radius (L): (18.0 x 0.9Di) inInside Knuckle Radius (ri): (18.0 x 0.17Di) inStraight Skirt Length (h): 1.500 inRadius L - (18.0 x 0.9Di) = 16.20 inRadius ri - (18.0 x 0.17Di) = 3.06 in
Material and Conditions:
Material: SA-202 Gr. B (Room Temperature)Internal Pressure: 200 psiAllowable Stress: 20,000 psiHead Longitudinal Joint Efficiency: 0.85Corrosion Allowance: 0.010 in
Variable:
L/r = L/ri = 16.20/3.06 = 5.29 in
a) Required Thickness:
t = PD + corrosion allowance2SE 0.2P
t = 200 x 18.0 + 0.0102(20,000)(0.85) 0.2(200)
t = 0.116 in.
b) Maximum Pressure:
P = 2SEt =D + 0.2t
P = 2(20,000)(0.85)(0.116) =18 + 0.2 (0.116)
P = 219 psi.
Note:Ellipsoidal heads and all torispherical heads having materials with minimum tensile strength 80,000 psi shall be designed using a value ofS = 20,000 psi at room temperature (see UG-23).
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6.3 - Torispherical Heads:
Shallow heads, commonly referred to as flanged anddished heads (F&D heads), are according to paragraphUG-32 (e), with a spherical radius L of 1.0D and aknuckle radius r of 0.06D.
a) Flanged & Dished Head (F&D heads):
The dish radius of a Flanged and Dished Head is 1.0 Dand the knuckle radius is 0.06% D. The requiredthickness of a Torispherical F&D Head with r/L = 0.06and L = Di, is:
and
P = Pressure on the concave side of the headS = Allowable stresst = Thickness of the headL = Inside spherical radiusE = Joint efficiency factor
Example 15 - Torispherical Heads:
A drum is to operate at 500F and 350 psi and to hold 5000gallons of water. The inside radius of thDished Torispherical Heads is 78 in. The material is SA 285 Grade A. Assume S = 11,200 psi and E= 0.85.
Solution: Dished Torispherical Heads with L = Di and r/L = 0.06, use equation 2.7.
t = 0.885 PL =SE 0.1P
t = 0.885 (350) (78) =(11200)(0.85) 0.1(350)
t = 2.54 in.
b) Non Standard 80-10 Flanged & Dished Head:
On an 80-10 the inside radius (L) is 0.8 Di and the knuckle radius (ri) is 10% of the head diameter. Fothe required thickness of a Non Standard 80-10 Head, use equations 2.7 and 2.8.
Designing 80-10 Torispherical Heads rather than standard shapes can be achieved by lowering thmaterial costs. The 80-10 is typically only 66% the thickness of the standard Torispherical Heads.
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6.4 Conical or Toriconical Heads:
The required thickness of the Conical or Toriconical Head (knuckle radius > 6% OD) shall be determineby formula using internal diameter of shell, 30.
t = PD 2.92 (SE - 0.6P) cos
L = Di / (2 cos )Di = Internal Diameter (conical portion) = D - 2 r (1 - cos )r = Inside Knuckle Radius
Toriconical Heads Definitions:
6.6 - Scope of ASME Section VIII:
Objective: Minimum requirements for safe construction and operation, Division 1, 2, and 3.
Section VIII Division 1:
15 psig < P 3000 psig
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Other exclusions:
Internals (except for attachment weld to vessel) Fired process heaters Pressure containers integral with machinery Piping systems
Section VIII, Division 2, Alternative Rules:
15 psig < P 3000 psig - identical to Division 1, but the different requirements are:
Allowable stress Stress calculations Design Quality control Fabrication and inspection
The choice between Divisions 1 and 2 is based mainly on economics of materials.
Division 3, Alternative Rules - High Pressure Vessels:
Applications over10,000 psi;Pressure from external source, process reaction, application of heat, combination of these;Does not establish maximum pressure limits of Division 1 or 2 or minimum limits for Division 3.
Structure of Section VIII, Division 1:
Subsection A: Part UG applies to all vessels;
Subsection B: Requirements based on fabrication method, Parts UW, UF, UB;
Subsection C: Requirements based on material class, Parts UCS, UNF, UHA, UCI, UCL, UCD, UHT,ULW, ULT. Mandatory and Nonmandatory Appendices
Determination ofMaterial Thickness:
Yield Strength, Ultimate Tensile Strength, Creep Strength, Rupture Strength and Corrosion Resistance.
Resistance to Hydrogen Attack:
-Temperature at 300 - 400F, monatomic hydrogen forms molecular hydrogen in voids;- Pressure buildup can cause steel to crack;- Above 600F, hydrogen attack causes irreparable damage through component thickness.
Brittle Fracture and Fracture Toughness:
The conditions that could cause brittle fracture are:
Typically at low temperature Can occur below design pressure No yielding before complete failure High enough stress for crack initiation and growth Low enough material fracture toughness at temperature Critical size defect to act as stress concentration
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Factors That Influence Fracture Toughness:
- Temperature- Type and chemistry of steel- Manufacturing and fabrication processes- Arc strikes, especially if over repaired area- Stress raisers or scratches in cold formed thick plate
Material Groups The Most Common Used Materials:
Curve A:
SA-216 Gr. WCB & WCC, normalized and tempered;SA-217 Gr. WC6, normalized and tempered.
Curve B:
SA-216 Gr. WCA, normalized and tempered or water-quenched and tempered;SA-216 Gr. WCB & WCC for maximum thickness of 2 in. (water-quenched and tempered);
SA-285 Gr. A & B;SA-414 Gr. A;SA-515 Gr. 60;SA-516 Gr. 65 & 70, not normalized.
Curve C:
SA-182 Gr. 21& 22, normalized and temperedSA-302 Gr. C & DSA-336 Gr. F21 & F22, normalized and temperedS A-3 8 7 G r. 21 & 22, normalized and temperedS A-5 1 6 G r. 55 & 60, not normalized
SA-533 Gr. B & CSA-662 Gr. A
Curve D:
SA-203SA-537 Cl. 1, 2 & 3SA-508 Cl. 1SA-612, normalizedSA-516, normalizedSA 662, normalizedSA-524 Cl. 1 & 2
SA-738 Gr. A
Bolting:
See the ASME Code Section VIII, Div. 1, for impact and nuts test for specified material specifications.
Addi tional ASME Code Impact Test Requirements
For welded construction over 4 in. thick, or non welded construction over 6 in. thick, if MDMT < 120F Not required for flanges if temperature -20F; required if SMYS > 65 ksi unless specifically exempt.
Weld Joint Efficiencies, E
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6.5 Resume of Pressure Vessels Formulae ASME Section I & ASME Section VIII:
Item Thickness - t (in)Pressure - P
(in)Stress - S (in) Notes
PR SEt P(R + 0.6t) t 0.25 D; P 0.385 SE
SE - 0.6P R + 0.6t t
PR 2.SEt P(R + 0.2t) t 0.178D; P 0.685 SE
2SE - 0.2P R + 0.2t 2t
Flat Flanged HeadD0.3P/S tS/0.3D 0.3D P/t
0.885PL SEt P(0.885L + 0.1t) r/L = 0.06; L D + 2t
SE - 0.1P 0.885L + 0.1t t
PLM 2.SEt P(LM + 0.2t) M = 3 + (L/r)1/2
/ 4
2SE - 0.2P LM + 0.2t 2t
PD 2.SEt P(D + 0.2t) h/D = 4
2SE - 0.2P D + 0.2t 2t
PDK 2.SEt P(DK + 0.2t) K = [2 + (D/2h)] / 6; 2 D/h 6
2SE - 0.2P DK + 0.2t 2Et
PD 2.SEt cos P(D + 1.2t cos ) 30
2(SE - 0.6P) cos D + 1.2t cos 2t cos
Cylindrical Shell
Torispherical Head (a)
Torispherical Head (b)
2:1 Semi-Elliptical Head
(a)
Toriconical Head
Ellipsoidal Head (b)
Hemispherical Shell (or
Head)
OBS.:
D = Shell / Head Inside Diameter, E = Weld Joint Efficiency (0.7 -1.0), L = Crown Radius, P = Internal Pressure, h = Inside Deptof Head, r= Knuckle Radius, R = Shell/Head Inside Radius, S = Allowable Stress, t = Shell / Head Thickness.
Common Materials - Temperature Limits:
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7.0 - Shell Nozzles Fundamentals:
Vessel components are weakened when material is removed to provide openings for nozzles or accessopenings. To avoid failure in the opening area, compensation or reinforcement is required.
The Code procedure is to relocate the removed material to an area within an effective boundary aroundthe opening. Figure bellow shows the steps necessary to reinforce an opening in a pressure vessel.
Definitions:
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Diameter of circular opening, d:
d = Diameter of Opening 2 (Tn + Corrosion Allowance)
Required wall thickness of the nozzle (min):
tn = PR......
SE 0.6P
Area of required reinforcement, Ar:
Ar= d.ts.F (in) =
Where:
d =Diameter of circular opening, or finished dimension of opening in plane under consideration, in.
ts = Minimum required thickness of shell when E = 1.0, in.
F = Correction factor, normally 1.0
Example 16 Basic Pipe Nozzle:
Basic design:
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Design Pressure = 300 psigDesign Temperature = 200 FShell Material is SA-516 Gr. 60Nozzle Diameter 8 in, Sch. 40Nozzle Material is SA-53 Gr. B, SeamlessCorrosion Allowance = 0.0625"
Vessel is 100% Radiographed
a) Wall thickness of the nozzle (min):
tn = PR...... =SE 0.6P
tn = 300 x 4.312.. + 0.0625 (Corrosion Allowance)12,000(1.0) 0.6(300)
tn = 0.11 + 0.0625= 0.17 in (min) Pipe Sch. 40 is t = 0.32in.
b) Circular opening, d:
d = Diameter of Opening 2 (Tn + Corrosion Allowance)
d = 8.625 2(0.32 + 0.0625) =
d = 8.625 2 (0.3825) = 7.86 in
c) Area of required reinforcement, Ar:
Ar= d.ts.F (in) =
Ar= 7.86 x 0.487 x 1.0 = 3.82 in
Available reinforcement area in shell, Ar, as larger ofAs or An:
As= Larger of: d (Ts ts) - 2 Tn (Ts ts) =
As = 7.86 (0.5625 0,487) 2x 0,5625 (0.5625 0,487) = 0.50 in
An =Smaller of: 2 [2.5 (Ts) (Tn tn)]
An =2 [2.5 (0.5625) (0.32 0.17)] = 0.42in
Ar< (As + An) =
Ar< (0.50 + 0.42) = 0.92 in < 3.82 in (Reqd.)
OBS.: Therefore, its necessary to increase Ts and / or Tn to attend the premise Ar < (As + An).
Example 17 Basic Shell & Nozzle:
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Design Pressure = 700 psi
Design temperature = 700 F
Nozzle Diameter = 8 in. (8.625 OD)
Material:
Shell SA 516 Gr.70
Head SA 516 Gr. 70
Nozzle SA 106 Gr. B
E = 1.0 (weld efficiency)
Required Shell Thickness:
ts= PRSE 0.6P
ts = 700 x 30..... = 1.30 (Use Ts = 1 1/2)16,600(1.0) 0.6(700)
Required Head Thickness:
th= PR2SE 0.2P
th = 700 x 30.......... = 0.64 (Use Th = 7/8)2(16,600)(1.0) 0.2(700)
Required Nozzle Thickness:
tn= PRSE 0.6P
tn = 700 x 4.312..... = 0.21 (Use Tn = 1/2)14,400(1.0) 0.6(700)
Opening Reinforcement:
Ar (Reqd.) = d.ts = 8.625 x 1.3 = 11.2 in
As = Larger of: d (Ts ts) - 2 Tn (Ts ts) =
As = 8.625 (1.5 1.3) 2 (1.0) (1.5 1.3) = 1.325 in
An = Smaller of: 2[2.5 (Ts) (Tn tn)]
An = 2[2.5 (1.5) (1.0 0.21)] = 5.925 in
Ar < (As + An) =
Ar < (1.325 + 5.925) = 7.25 in < 11.2 (Reqd.)
OBS.: Necessary to increase Ts and / or Tn toattend the premise (As + An) > Ar.
Example 18 Nozzle Design:
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8.0 ASME Materials:
The following Tables indicates the most common ferrous materials used in Pressure Vessels design anfabrication, including structural plates, pipes, tubes, castings, forgings, flanges, fittings, bolts and nutsBeyond the knowledge of the most common ferrous materials, the Tables also help the student how tsearch the materials MAWP (Maximum Allowable Stress Values) in ASME Section II, Table 1A.
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8.1 - Carbon Steels:
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8.2 - Low Alloy Steels:
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8.1 MAWP Maximum Allowable Stress Values
The Section II, Part D contains properties of ferrous and nonferrous materials adopted by the Code fothe design of boiler, pressure-vessel, and nuclear-power-plant components including tables of thmaximum allowable stresses and design-stress intensities for the materials adopted by various Codeboosections.
The tables below are an extract from ASME for the most common ferrous materials for a design purpose.
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9.0 - Suplementary Design Formulas:
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Example 19 MAWP (Maximum Allowable Working Pressure:
Example 20 Thickness of a Cylindrical Shell Considering Internal Pressure
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Example 21 Design of a Standard Torispherical Head
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Example 22 Design of a Non-Standard Torispherical Head
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