Corrosion Resistant Alloys
40
General Guidelines for Welding, Brazing, Hot and Cold Working, Heat Treating, Pickling and Finishing H-2010F FABRICATION OF HASTELLOY ® CORROSION-RESISTANT ALLOYS CORROSION-RESISTANT ALLOYS Contents Introduction 2 Welding 3 Safety and Health Considerations 15 Brazing 16 Lining 18 Hot Working 25 Cold Working 27 Heat Treatment 30 Descaling and Pickling 32 Grinding and Machining 34 Appendix - Selected Data and Information 37 Chemical Compositions 37 Available Forms 38 Wire and Electrode Sizes 38 ASME and AWS Specifications 38 Comparative Properties 38 Thermal Expansion 39 Thermal Conductivity 39 Sales Offices Addresses 40 © 2003, Haynes International, Inc.
Transcript of Corrosion Resistant Alloys
1
General Guidelines forWelding, Brazing, Hot andCold Working, Heat Treating,Pickling and Finishing
H-2010F
FABRICATION OF HASTELLOY®
CORROSION-RESISTANT ALLOYS
CORROSION-RESISTANT ALLOYS
Contents
Introduction 2
Welding 3Safety and HealthConsiderations 15Brazing 16
Lining 18
Hot Working 25
Cold Working 27
Heat Treatment 30
Descaling and Pickling 32
Grinding and Machining 34Appendix - SelectedData and Information 37
Chemical Compositions 37
Available Forms 38
Wire and Electrode Sizes 38ASME and AWSSpecifications 38Comparative Properties 38
Thermal Expansion 39
Thermal Conductivity 39
Sales Offices Addresses 40
© 2003, Haynes International, Inc.
2Introduction
INTRODUCTIONThis brochure is a general guide tothe fabrication of the corrosion-resistant alloys produced by HaynesInternational, Inc. It is not to beconsidered as a detailedinstruction manual.
The following corrosion-resistantalloys covered in detail in this guideinclude:
HASTELLOY ® B-2 alloyHASTELLOY B-3 ® alloyHASTELLOY C-4 alloyHASTELLOY C-22® alloyHASTELLOY C-2000 ® alloyHASTELLOY C-276 alloyHASTELLOY G-30 ® alloyHASTELLOY N alloy
HASTELLOY B-2 alloy is a nickel-based wrought alloy with excellentresistance to hydrochloric acid at allconcentrations and temperatures. Italso withstands hydrogen chloride,sulfuric, hydrofluoric, acetic, andreagent grade phosphoric acids.The alloy has excellent resistance tostress corrosion cracking and toknife-line and heat-affected zoneattack. It resists the formation ofgrain-boundary carbide precipitatesin the weld heat-affected zone, thusmaking it suitable for use in specificchemical process applications in theas-welded condition.Ask for Bulletin H-2006
HASTELLOY B-3 alloy is anadditional member of the nickel-molybdenum family of alloys withexcellent resistance to hydrochloricacid at all concentrations andtemperatures. It also withstandssulfuric, acetic, formic andphosphoric acids, and othernonoxidizing media. B-3 alloy has aspecial chemistry designed toachieve a level of thermal stabilitygreatly superior to that of itspredecessors, e.g. HASTELLOYB-2 alloy. B-3 alloy has excellentresistance to pitting corrosion, tostress-corrosion cracking, and toknife-line and heat-affected zoneattack.Ask for Bulletin H-2104
HASTELLOY C-4 alloy is a nickel-chromium-molybdenum alloy withoutstanding high-temperaturestability, as evidenced by highductility and corrosion resistanceeven after longtime aging at 1200 to1900°F (649 to 1038°C). The alloyalso has excellent resistance tostress corrosion cracking and tooxidizing atmospheres up to 1900°F(1038°C).Ask for Bulletin H-2007
HASTELLOY C-22 alloy – aversatile nickel-chromium-molybdenum-tungsten alloy withbetter overall corrosion resistancethan other Ni-Cr-Mo-W alloysavailable today, includingHASTELLOY C-276 and C-4 alloysand HAYNES 625 alloy. C-22 alloyhas outstanding resistance to pitting,crevice corrosion, and stresscorrosion cracking. By virtue of itshigher chromium content, C-22 alloyis more resistant than C-4 andC-276 alloys to oxidizing acids andto acid streams containing oxidizingresiduals such as dissolved oxygen,ferric ions, and wet chlorine. In fact,it is second only to C-2000 alloy inits versatility. Because of suchversatility it can be used in multi-purpose processes and where"upset" conditions are likely to occur.Ask for Bulletin H-2019
HASTELLOY C-2000 alloy wasdesigned to resist an extensiverange of corrosive chemicals,including sulfuric, hydrochloric, andhydrofluoric acids. Unlike previousNi-Cr-Mo alloys, which wereoptimized for use in either oxidizingor reducing acids, C-2000 alloyextends corrosion resistance in bothtypes of environments. Thecombination of molybdenum andcopper provide the outstandingresistance to reducing media, whileoxidizing acid resistance is providedby a high chromium content. C-2000alloy also exhibits pitting resistanceand crevice corrosion resistancesuperior to the industry standard,C-276 alloy. Its forming, welding,and machining characteristics aresimilar to C-276 alloy.Ask for Bulletin H-2111
HASTELLOY C-276 alloy hasexcellent resistance to pitting, stresscorrosion cracking, and acidenvironments. It has exceptionalresistance to a wide variety ofchemical process environments,including strong oxidizers such asferric and cupric chlorides, hotcontaminated media (organic andinorganic), chlorine, formic andacetic acids, acetic anhydride, andseawater and brine solutions.Ask for Bulletin H-2002
HASTELLOY G-30 alloy is a highchromium nickel-based alloy whichshows superior corrosion resistanceover most other nickel- and iron-based alloys in commercialphosphoric acids as well as manycomplex environments containinghighly oxidizing acids such as nitric/hydrochloric, nitric/hydrofluoric, andsulfuric acids. The resistance ofG-30 alloy to the formation of grainboundary precipitates in the heat-affected zone makes it suitable foruse in the as-welded condition.Ask for Bulletin H-2028
HASTELLOY N alloy is a nickel-based alloy that was developed as acontainer material for molten fluoridesalts. It has good oxidationresistance to hot fluoride salts in thetemperature range of 1300 to1600°F (704 to 871°C). Alloy N ismost useful in environmentsinvolving fluorides at hightemperatures; however, the alloycompares favorably with otherHASTELLOY alloys in various othercorrosive media. It is especiallysuggested that the alloy be tested inmolten halides of zirconium,beryllium, lithium, sodium,potassium, thorium, or uranium.Ask for Bulletin H-2052
The nominal chemical compositionsof these alloys and the availableproduct forms can be found inTables A-1 and A-2, respectively, inthe Appendix.
© 2003 by Haynes International, Inc.
3
General WeldingThe welding characteristics of theHASTELLOY® corrosion-resistantalloys are similar in many ways tothose of the austenitic stainlesssteels and present no specialwelding problems, if propertechniques and procedures arefollowed.
As a way of achieving qualityproduction welds, developmentand qualification of weldingprocedure specifications issuggested. Such procedures areusually required for codefabrication, and should take intoaccount parameters such as, butnot limited to, base and fillermaterials, welding process, jointdesign, electrical characteristics,preheat/interpass control, andpostweld heat treatmentrequirements.
Any modern welding power supplywith adequate output and controlsmay be used with the commonfusion welding processes.Generally, welding heat input iscontrolled in the low to moderaterange. Wide weave beads are notrecommended. Stringer beadwelding techniques, with someelectrode/torch manipulation, arepreferred.
WELDING
Welding
In general, nickel-based alloys willexhibit both sluggish welding andshallow penetration characteristics.Therefore, care must be used withrespect to joint design and weldbead placement to insure thatsound welds with proper weldbead tie-in are achieved. Thenickel-based alloys have atendency to crater crack, sogrinding of starts and stops isrecommended.
Cleanliness is considered animportant aspect of welding of thecorrosion-resistant nickel-basedalloys. Contamination by greases,oils, corrosion products, lead,sulfur, and other low melting pointelements can lead to severecracking problems.
It is recommend that welding beperformed on base materialsthat are in the solution annealedcondition. Materials with > 7%outer Fiber Elongations of coldwork should be solutionannealed before welding. Thewelding of mateials have largeamounts of residual cold workcan lead to cracking in the weldmetal and/or the weld heataffected zone. Welding processesthat are commonly used with thecorrosion-resistant alloys are shownin Table 1.
In addition to these common arcwelding processes, other weldingprocesses such as plasma arcwelding, resistance spot welding,laser beam welding, electron beamwelding, and submerged arcwelding can be used. Because ofthe possibility of hot cracking,parameter selection is extremelyimportant when using thesubmerged arc welding process toweld nickel-based alloys. ContactHaynes International for weldingparameter and wire/fluxrecommendations.
The plasma arc cutting process iscommonly used to cut alloy plateinto desired shapes and prepareweld angles.
The use of oxyacetylene weldingand cutting is not recommended,because of carbon pick-up fromthe flame.
TABLE 1
American Welding CommonProcess Society Designation Designation
Gas Tungsten Arc Welding,Manual and Machine GTAW TIGGas Metal Arc Welding,Manual and Machine GMAW MIG
Stick or CoatedShielded Metal Arc Welding SMAW Electrode
4
Selection of welding filler materialsis a critical element in the design ofa corrosion-resistant welded struc-ture. Often, several types of corro-sion-resistant alloys are used atvarious locations in the samestructure. The selection of weldingfiller materials for dissimilar metaljoining applications is also critical.
Two methods of welding filler ma-terial selection are possible. Theyare (1) selection of matching fillermaterials and (2) selection ofoveralloyed filler materials. Whenthe matching filler material tech-nique is used, the filler material isof the same chemical compositionas one or both of the base materi-als. In dissimilar welding applica-tions, using the matching filler ma-terial technique, the filler material ischosen to match the base materialwhich is generally more highly al-loyed (more corrosion resistant).
With the overalloyed filler materialselection technique, a highly al-loyed, highly corrosion-resistantwelding filler material is used. (Fig-ures 1 and 2).
Overalloyed filler metal selectionreduces the chance of preferentialweld metal corrosion attack. In ad-dition, the use of a singleoveralloyed filler material on a jobsite greatly reduces the chance offiller metal mix-up. HASTELLOYC-22 and C-2000 alloys are usedextensively as such overalloyedwelding filler materials.
Additional information concerningoveralloyed welding filler metal se-lection is contained in BrochureH-2062, Universal Weld FillerMetal.
Table 2A contains a list of filler ma-terials which are available fromHaynes International, Inc. Table 2Boffers suggestions for selection offiller materials, under both similarand dissimilar welding applica-tions, using both matching andoveralloyed selection techniques.
The base material combinations,which apply to a particular applica-tion, are selected along a horizon-tal row and a vertical column ofTable 2B. The numbers listed at
that intersection represent possiblewelding filler materials as listed inTable 2A.
The information included hereuses the same filler metal "alloyclass" designation as is used inBrochure H-3167. It is possible,then, to cross-reference the infor-mation listed in Brochure H-3167without confusion.
When joining the HASTELLOY al-loy base materials to carbon steelor low-alloy steel, the arc mayhave a tendency to play onto thesteel side of the weld joint. Propergrounding techniques, a short arclength and torch/electrode manipu-lation are necessary to compen-sate for this problem.
Additional information on appli-cable filler metal specificationsand product forms are contained inthe Appendix at the end of this bro-chure.
SELECTION OF WELDING FILLER MATERIAL
Welding
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Figure 1
GAS TUNGSTEN ARC WELDS (GTAW)
317L Stainless SteelBase Metal9% FeCl
3 Solution;
950F (350C), 120-hour test
Alloy 904LBase Metal9% FeCl
3 Solution;
950F (350C), 120-hour test
317L Stainless SteelBase Metal9% FeCl3 Solution;950F (350C), 120-hour test
Alloy 904LBase Metal9% FeCl
3 Solution;
950F (350C), 120-hour test
Figure 2
SHIELD METAL ARC WELDS (SMAW)
Alloy 317L Alloy 625 C-22® AlloyFiller Metal Filler Metal Filler Metal
Alloy 904L Alloy 625 C-22 AlloyFiller Metal Filler Metal Filler Metal
IN-182 (600-type) IN-112 (625-type) C-22 AlloyElectrode Electrode Electrode
IN-182 (600-type) IN-112 (625-type) C-22 AlloyElectrode Electrode Electrode
Welding
6
Filler Materials AWS A5.11/A5.14 Alloy ClassHASTELLOY® B-2 alloy E*/ER**NiMo-7 10HASTELLOY B-3® alloy E/ERNiMo-10 11HASTELLOY C-276 alloy E/ERNiCrMo-4 12HASTELLOY C-22® alloy E/ERNiCrMo-10 13HASTELLOY C-4 alloy E/ERNiCrMo-7 14HASTELLOY C-2000® alloy E/ERNiCrMo-17 15HASTELLOY G-30® alloy E/ERNiCrMo-11 17HASTELLOY W alloy E/ERNiMo-3 20HAYNES® 242TM alloy - 9HAYNES 625 alloy ERNiCrMo-3 8*E - Coated Electrodes**ER - Bare Wire
Table 2A
WELDING FILLER MATERIALS
Table 2B
SUGGESTED FILLER METAL SELECTION GUIDE
For both Matching and Overalloyed Filler Materials
Welding
Alloys B-2 B-3® C-4 C-276 C-22® C-2000® G-30® N
HASTELLOY® 10B-2 alloy 11HASTELLOY 11 11B-3 alloy 10 10HASTELLOY 10 11 14C-4 alloy 11 10 13
13 1314 14
HASTELLOY 10 11 13 12C-276 alloy 11 10 14 13
13 13 1212 12
HASTELLOY 10 11 13 13 13C-22 alloy 11 10 14 12
13 13HASTELLOY 10 11 13 13 13 15C-2000 alloy 11 10 14 15 15 13
13 13 15 1215 15
HASTELLOY 10 11 13 13 13 13 17G-30 alloy 11 10 14 12 17 15
13 13 17 17 1717 17
HASTELLOY 9 9 9 9 9 9 9 9N alloy 20 20 20 20 20 20 20 20
10 11 14 12 13 15 1711 10
200/201 10 11 14 12 13 15 17 811 10 13 13 13 13 9
400 8 8 8 8 8 8 8 8600 10 11 14 12 13 15 17 9
8 8 8 8 8 8 8 8825 10 11 14 12 13 15 17 9
13 13 13 13 13 13 13Stainless and 10 11 14 12 13 15 17 9Carbon 13 13 13 13 13 13 13Steel 8 8 8 8 8 8 8 8
7 Welding
Selection of a correct weld jointdesign is critical to the success-ful fabrication of HASTELLOYcorrosion-resistant alloys. Poorjoint design can negate even themost optimum selection ofwelding filler metal.
Various welding documents areavailable to assist in the designof welded joints. Two suchdocuments that provide guid-ance are American WeldingSociety, Welding Handbook,Volume 1, Eighth Edition,Chapter 5 and ASM Interna-tional, Metals Handbook, Vol-ume 6, Welding, Brazing andSoldering, Joint Design andPreparation. In addition, fabrica-tion codes such as the ASMEPressure Vessel and PipingCode may impose designrequirements.
Typical butt joint designs that areused with the gas tungsten arcwelding (GTAW), gas metalarc welding (GMAW), and
WELDING JOINT DESIGN
shielded metal arc welding(SMAW) processes are (I)Square-Groove, (II) Single-V-Groove, and (III) Double-V-Groove shown in Figure 3. Gastungsten arc welding is often thepreferred method for depositingthe root pass associated with thesquare-groove (Joint I) or single-groove (Joint II) where access toonly one side of the joint ispossible. The remainder of thejoint can then be filled usingother welding processes asappropriate. For groove weldson heavy section plates greaterthan 3/4 inch (19 mm) thick, a J-groove is permissible. Such ajoint reduces the amount of fillermetal and time required tocomplete the weld. Other typicalwelding joint designs are shownin Figure 4. The actual numberof passes required to fill the jointdepends upon a number offactors that include the fillermetal size (electrode or wirediameter), the amperage, andthe travel speed.
It should be recognized thatnickel-based alloy weld metal issluggish (not as fluid as carbonsteel) and does not flow out asreadily and "wet" the sidewalls.Therefore, the welding arc andfiller metal must be manipulatedso as to place the molten metalwhere needed. In addition to thesluggishness, the joint penetra-tion is also less than that of atypical carbon or stainless steelweld. With this low penetrationpattern, the possibility of incom-plete fusion increases. As aresult of these factors, care mustbe taken to insure that thegroove opening is wide enoughto allow proper torch or electrodemanipulation and placement ofthe weld bead.
A general estimate of filler metalrequirements is about four to fivepercent (by weight) of the baseplate requirement. Estimatedweight of weld metal required perunit length of welding is given inTable 3.
TABLE 3
Included Approx. WeightMaterial Preferred Root Land Weld of Weld MetalThickness (t), Joint Opening (A), Thickness (B) Angle (C), Required,in. (mm) Design in (mm) in (mm) degrees lbs/ft (kg/m)1/16 (1.6) l 0-1/16 (0-1.6) N/A None 0.02 (0.03)3/32 (2.4) I 0-3/32 (0-2.4) N/A None 0.04 (0.06)1/8 (3.2) I 0-1/8 (0-3.2) N/A None 0.06 (0.09)1/4 (6.3) II 1/16-1/8 (1.6-3.2) 60-75 0.30 (0.45)3/8 (9.5) II 60-75 0.60 (0.89)1/2 (12.7) II 60-75 0.95 (1.41)1/2 (12.7) III 1/32-5/32 1/32-3/32 60-75 0.60 (0.89)5/8 (15.9) II (0.8-4.0) (0.8-2.4) 60-75 1.40 (2.08)5/8 (15.9) III 60-75 0.82 (1.22)3/4 (19.1) II 60-75 1.90 (2.83)3/4 (19.1) III 60-75 1.20 (1.79)
Figure 3
TYPICAL BUTT JOINTS FOR MANUAL WELDING
←↑
↑ ←←
Joint I
A
t ↑
←
↑ ←
↑
↑C
AB
↑
Joint II
←
↑
←
↑ ←
↑ ↑C
A
B
↑
Joint III
tt
8
Figure 4
OTHER JOINT DESIGNS FOR SPECIFIC SITUATIONS
Flanged corner weld not recommended for shielded metal arc welding. No filler rod required for gas tungsten arc welding.
Flanged Corner Weld
1/16” & 3/32”
1 1/2 T
For joints requiring maximum penetration. t=greater than 1/4-inch (6.4 mm). Difficult weld.
t
45°
1/16” to 3/32”
60 - 75°
Butt joint (chisel weld) for round bars up to 1 1/2 inches (38 mm) in diameter.
Conventional fillet weld. Fillet size should equal thickness of thinnest member.
Shell Plate Openings
For side openings such as manways, viewports, pipe flanges, etc. Not to be confused with tube shells.
Butt joint (chisel weld) for round bars over 1 1/2 inches (38 mm) in diameter.
Shell Plate
1/16” min.
45° 15°
3/32” to 1/8”
t
T
t
Cleaning, Edge Preparationand Fit-UpProper preparation of the weld jointregion is considered a veryimportant part of welding thecorrosion-resistant nickel-basedalloys. A variety of mechanical andthermal cutting methods areavailable for the preparation ofweld angles. Plasma cutting/gouging, machining, grinding, andair carbon arc gouging are allpotential processes. It is necessaryto condition all thermal cut edgesto bright, shiny metal prior towelding. (This is particularlyimportant if air arc gouging is beingused due to the extreme possibilityof carbon pick-up from the carbonelectrode).
In addition to the weld angle, aone-inch (25 mm) wide band onthe top and bottom (face and root)surface of the weld zone should beconditioned to bright metal withabout an 80 grit flapper wheel ordisk. This is essential whenshielded metal arc weldingHASTELLOY B-2/B-3 alloys. If themill scale is not removed, the B-2/B-3 alloys welding flux can interactwith the mill scale and causecracking at the toe of the weld inthe base material.
The welding surface and adjacentregions should be thoroughlycleaned with an appropriatesolvent prior to any welding
operation. All greases, cutting oils,crayon marks, machiningsolutions, corrosion products,paints, scale, dye penetrantsolutions, and other foreign mattershould be completely removed.
Stainless steel wire brushing isnormally sufficient for interpasscleaning of GTAW and GMAWweldments. The grinding of startsand stops is recommended for allfusion welding processes. Ifoxygen or carbon dioxide bearingshielding gases are used duringgas metal arc welding, lightgrinding is necessary betweenpasses prior to wire brushing. Slagremoval during shielded metal arcwelding will require chipping andgrinding followed by wire brushing.
Surface iron contamination (ruststaining) resulting from contact ofcarbon steel with the nickel-basedalloys is not considered a seriousproblem and, therefore, it isgenerally not necessary to removesuch rust stains prior to service. Inaddition, melting of small amountsof such surface iron contamination,into the weld puddle, is notexpected to affect weld metalcorrosion resistance.
While such contamination is notconsidered a serious problem, it isassumed that reasonable care isexercised to avoid the problem tobegin with. If such care is
exercised, no particular correctivemeasures should be necessaryprior to service.
Preheat, InterpassTemperature, and CoolingTechniquesPreheat of the HASTELLOY alloysis not required. Preheat isgenerally specified as roomtemperature (typical shopconditions). Interpass temperatureshould be maintained below 200ºF(93ºC).
The base plate may requirewarming to raise the temperatureof the alloy above freezing or toprevent condensation of moisture.Condensation may occur if thealloy is brought into a warm shopfrom cold outdoor storage.Warming should be accomplishedby indirect heating if possible(infrared heaters or natural heatingto room temperature).
If oxyacetylene warming is used,the heat should be applied evenlyover the base metal rather than inthe weld zone. The torch should beadjusted so that the flame is notcarburizing. A "rosebud" tip, whichdistributes the flame evenly, isrecommended. Care should betaken to avoid local or incipientmelting as a result of the warmingprocess.
Welding
9
Auxiliary cooling methods may beused to control the interpasstemperature. Water quenching isacceptable. Care must be taken toinsure that the weld zone is notcontaminated with traces of oilfrom shop air lines, grease or dirtfrom soiled water-soaked rags, ormineral deposits from hard waterused to cool the weld joint. Thesafest way to maintain a lowinterpass temperature is to allowthe assembly to cool naturally.When attaching hardware to theoutside of a thin-walled vessel, it isgood practice to provide auxiliarycooling to the inside (process side)to minimize the extent of the heat-affected zone.
Postweld Heat TreatmentHASTELLOY corrosion-resistantalloys, under the vast majority ofcorrosive environments, are usedin the as-welded condition.Postweld heat treatments, eitherfull solution anneal heat treatment,1900 to 2150ºF (1038 to 1177ºC)depending on alloy, or stress reliefheat treatment, typically 1100 to1200ºF (593 to 649ºC), arenormally not required.
Specific discussions concerningsolution annealing requirementsare presented in the HeatTreatment section of this brochure.
Stress relief heat treatments arenormally considered to beineffective with these alloys andcan in some cases affectmechanical properties.HASTELLOY B-2 and B-3 alloysfor example, should never be heattreated or postweld stressrelieved in the 1000 to 1500ºF(538 to 816ºC) temperature range.If stress relief heat treatment ofattendant carbon steel componentsections is required to meet coderequirement, contact HaynesInternational, Inc. for detailedinformation.
Inspection and RepairGood manufacturing practicesuggests that some degree ofnondestructive testing (NDT) beconducted. For code fabrications,certain mandatory NDTinspections may be required. Fornon-code fabrication, NDT may beas simple as visual inspection ordye penetrant inspection. NDTshould be considered for bothintermediate quality controlinspections during fabrication, aswell as for final acceptance tests.
Welding defects that are believedto affect quality or mechanicalintegrity should be removed andweld repaired. Removaltechniques include grinding,
plasma arc gouging, and aircarbon arc gouging. Extreme caremust be used during air carbon arcgouging to insure that carboncontamination of the weld zonedoes not occur.
Generally the prepared cavity isdye penetrant inspected to insurethat all objectionable defects havebeen removed and then thoroughlycleaned prior to welding repair.Because these alloys have lowpenetration characteristics, theground cavity must be broadenough and have sufficientsidewall clearance in the weldgroove to allow for weld rod/weldbead manipulation. "Healingcracks" or "washing out" defects byautogeneously remelting weldbeads or by depositing additionalfiller metal over the defect is notrecommended.
Control of DistortionDistortion characteristics of thenickel-based alloys are similar tothose of the austenitic stainlesssteels. Figure 5 is included to showpossible changes in weld jointshape.
Drawings arecourtesy ofWELDINGENCYCLOPEDIA,Monticello Books,Inc.
Transverse shrinkage of weld
Angular distortion of butt weld
Longitudinal shrinkage of weld
Angular distortion of filler weld
Neutral axis Pulling effects of weld
Center of gravity of weld
Pulling effect of weld above neutral axis
Neutral axis
Pulling effects of weld
Center of gravity of weld
Pulling effect of weld below neutral axis
Longitudinal neutral axisof member
Figure 5
CONTROL OF DISTORTION
Welding
10Welding
SPECIFIC WELDING PROCESS CONSIDERATIONS
Jigs, fixturing, cross supports,bracing, and bead placement/ weldsequence will help to holddistortion to a minimum. Wherepossible, balanced welding aboutthe neutral axis will assist inkeeping distortion to a minimum.Proper fixturing and clamping ofthe assembly makes the weldingoperation easier and minimizesbuckling and warping of thinsections.
It is suggested that, wherepossible, extra stock be allowed tothe overall width and length.Excess material can then beremoved to hold final dimensions.
Cracking ConsiderationsDuring normal fabrication of theHASTELLOY alloys, cracking israre and one should expect tofabricate large, complexcomponents with few problems.Fabrication cracking, when noted,can include hot cracking, stresscracking, and cracking related toheat treatment.
Hot cracking is a conditiongenerally confined to the fusionzone but occasionally can occur inthe heat-affected zone. Twoconditions are necessary toproduce hot cracking: stress and a"strain intolerant microstructure".
The creation of stress is inevitableduring welding because of thecomplex thermal stresses that arecreated when metal solidifies."Strain intolerant microstructures"temporarily occur at elevatedtemperatures near the melting andsolidification point of all alloys.Surface contaminates such assulfur can contribute to hotcracking. Certain geometricfeatures such as concave welddeposits and tear-drop shapedweld pools can also lead to hotcracking. For each alloy system, acritical combination of theseconditions can produce hotcracking.
For the HASTELLOY corrosion-resistant alloys, the onset of hotcracking has been observed whenwelding current reaches about 350amps in restrained,uncontaminated GMAW (spraytransfer mode) welds. Hot crackinghas also been found in C-276 alloysubmerged arc welds when theamperage was above 400 amps.
Cold cracking will occur insolidified weld metal and in basematerial only when externallyapplied stresses exceed the tensilestrength of the alloy. Classicalhydrogen embrittlement is not afabrication cracking problem innickel-based alloys.
Bead shape can play a role in weldmetal cracking. Root pass weldbeads that have a concave shapecan crack during root passwelding. This results from theapplied stresses exceeding thestrength limit of the very small weldbead cross-section. Convex weldbeads and clamps/fixtures cancontrol this cracking problem.
Weldments of HASTELLOY B-2alloy can suffer cracking duringheat treatment. Such crackingoccurs in the temperature range1000 to 1500ºF (538 to 816ºC)upon heat-up during solution heattreatment. In this temperaturerange the alloy becomes verystrong, with an attendant decreasein ductility due to the metallurgicalcondition known as long rangeordering. Residual tensile stressesin conjunction with the highstrength causes the alloy to crack.This condition is controlled by rapidheating during annealing and shotpeening high residual stress areas.More information concerning thisproblem is included in the HeatTreatment section of this brochure.B-3 alloy is a significantimprovement; however, crackingwill occur if longer exposure timein the deleterious temperaturerange.
Gas Tungsten Arc Welding(GTAW)The gas tungsten arc weldingprocess is a very versatile, all-position welding process. It can beused in production as well asrepair situations. It can be usedmanually or adapted to automaticequipment to weld thin sheet orplate material. It is a process thatoffers great control and is thereforeroutinely used during tack weldingand root pass welding. The majordrawback of the process isproductivity. For manual weldingsituations, GTAW weld metaldeposition rates are low.
Generally, power suppliesequipped with high frequency start,pre-purge/post-purge and up-slope/down-slope (or foot pedal)controls are recommended. It isrecommended that the GTAWwelding torch be equipped with agas diffuser screen ("gas lens") toprovide optimum shielding gascoverage. Generally, the gas cupshould be as large as practical.
Typical welding parameters, whichare suggested for theHASTELLOY corrosion-resistantalloys, are presented in Table 4.Electrical polarity should be directcurrent electrode negative(DCEN).
Two percent thoriated tungstenelectrodes are recommended. Theclassification for these electrodesis EWTh-2 (American WeldingSociety Specification A5.12). Thediameter of the tungsten electrodewill vary with amperage. Generalrecommendations for electrodediameter selection are given inTable 4. It is recommended thatthe electrode be ground to a coneshape (included angle of 30 to 60degrees) with a small 1/16 inch(1.6 mm) flat ground at the point.See Figure 6 for details.
11 Welding
Figure 6
TYPICAL MANUAL GAS TUNGSTEN ARC PARAMETERS (FLAT POSITION)*
Table 4
Welding grade argon (99.996percent minimum purity) shieldinggas is recommended for all normalfabrication situations. The flowrates are normally in the 25-30cubic feet per hour range. Whenproper shielding is achieved, theas-deposited weld metal shouldhave a bright-shiny appearanceand require only minor wirebrushing between passes. Onspecial occasions, argon-helium orargon-hydrogen shielding gasesare used in high travel speed,highly specialized mechanizedwelding systems.
In addition to welding torchshielding gas, a back-purge at theroot side of the weld joint isrecommended (welding gradeargon). The flow rates are normallyin the 5 to 10 cubic feet per hourrange. Often backing bars (usuallycopper) are used to assist in beadshape on the root side of GTAWwelds. Backing gas is oftenintroduced through small holesalong the length of the backing bar.
There are situations wherebacking bars cannot be used.Under these conditions, open-buttwelding is often performed. Suchwelding conditions are oftenencountered during pipe or tube
circumferential butt welding. Underthese conditions where access tothe root side of the joint is notpossible, special gas flowconditions have been establishedwhich differ from the industryrecommendations publishedelsewhere. Under these open-buttpipe welding conditions, the torchflow rates are reduced to about 10cubic feet per hour and the backpurge flow rates are increased toabout 40 cubic feet per hour. Adetailed brochure is availableconcerning back-purging duringpipe welding (ask for BrochureH-2065).
It is recommended that the torchbe held essentially perpendicularto the work piece. Stringer beadtechniques, using only enough
current to melt the base materialand allow proper fusion of the filler,are recommended. Duringwelding, the tip of the welding fillermaterial should always be heldunder the shielding gas to preventoxidation of the hot welding fillerwire. Standing still or puddling theweld adds to the welding heatinput is not recommended.
Since the welder controls fillermetal additions to the weldpuddle, care must be taken toensure that the resultant weldbead dilution of the basematerials is minimized.
Grinding MarksRun This Direction
.040 in.
.060 in.
30°to 60°
TungstenElectrode Filler Wire Welding
Joint Thickness Diameter Diameter Currentin (mm) in (mm) in (mm) Amps Volts
0.030-0.063 (0.8-1.6) 0.063 (1.6) 0.063 (1.6) 15-60 9-120.063-0.125 (1.6-3.2) 0.063/0.094 (1.6/2.4) 0.063/0.094 (1.6/2.4) 50-95 9-120.125-0.250 (3.2-6.3) 0.094/0.125 (2.4/3.2) 0.094/0.125 (2.4/3.2) 75-150 10-13
0.250 (6.3) and up 0.094/0.125 (2.4/3.2) 0.094/0.125 (2.4/3.2) 95-200 10-13* DCEN
TUNGSTEN ELECTRODE GEOMETRY
12
TYPICAL GAS METAL ARC WELDING PARAMETERS (FLAT POSITION)*Table 5
Gas Metal Arc Welding(GMAW)The gas metal arc welding processprovides a considerable increasein productivity when compared tothe gas tungsten arc weldingprocess. It is well suited for bothmanual and automatic weldingsituations. The weld metaldeposition rate is considerablyhigher but to some extent, controland ease of operation are reducedwith the GMAW process.
Three modes of weld metaltransfer are possible with gasmetal arc welding. They are shortcircuiting transfer, globular transfer,and spray transfer. The short arc
transfer mode is used in allwelding positions, provides goodweld puddle control, and isconsidered to be a low heat inputwelding process. However,because the process operates atlow amperage, it is often regardedas a defect (cold lap) proneprocess. The globular mode ofweld metal transfer is rarelyrecommended by HaynesInternational, except for weldoverlay cladding applications. Thespray transfer mode is useful onlyin the flat position and ischaracterized as a moderate tohigh heat input welding processwith relatively high depositionrates. The pulse-spray mode (amodified spray transfer mode) isuseful in all welding positions and
is less susceptible to cold lapdefects when compared to shortcircuiting mode.
Constant current, fixed frequencypulse, variable slope/inductanceand synergic welding powersupplies can all be used with theGMAW welding process. Theselection of weld metal transfermode (spray, synergic, pulse-sprayor short circuiting mode) must bedecided upon first. Such a decisionrequires information on jointdesign/thickness, welding positionto be used, required depositionrates, and welder skill levels. Fromthat information, the welding powersupply and welding parameterselections can be made.
Short Circuiting Mode
0.035 Ar+He 70-90 18-20
(0.9) He+Ar+CO2 70-90 17-20
Ar+He+CO2 70-90 17-20
0.045 Ar+He 100-160 19-22
(1.1) He+Ar+CO2 100-160 19-22
Ar+He+CO2 100-160 19-22
Spray Transfer Mode
0.045 Ar 190-250 30-32 300-350
(1.1) (7.6-8.9) 3/8 (9.5)
Ar+He+CO2 190-225 30-32 275-325 and up
(7.0-8.3)
Fixed Frequency Pulse Mode (60 & 120 CPS)
0.045 Ar+He 120-150 18-20 175-225 1/8-3/4
(1.1) peak, 250-300 (4.4-5.7) (3.2-19.1)
Ar+He+CO2 120-150 18-20 175-225 1/8-3/4
peak, 250-300 (4.4-5.7) (3.2-19.1)
Synergic Mode***
0.035 Ar+He 50-125 - - 0.062 (1.6) and up
(0.9) Ar+He+CO2 50-125 - - 0.062 (1.6) and up
0.045 Ar+He 100-175 - - 3/16 (4.8) and up
(1.1) Ar+He+CO2 100-175 - - 3/16 (4.8) and up
Wire Welding Welding Wire Feed JointDiameter Shielding Current, Voltage, Speed, Thicknessin. (mm) Gas** Amps Volts in./min. (m/min.) in. (mm)
* DCEP** Ar+He=75% argon+25% helium; He+Ar+Co2=90% helium+7.5% argon+2.5% carbon dioxide; Ar+He+Co2=69% argon+30% helium+1% carbon dioxide; Ar=100% argon.*** Detailed welding parameters are difficult to report because each welding machine uses unique set-up parameters to achieve proper welding characteristics.
150-200 0.050-3/16
(3.8-5.1) (1.3-4.8)
175-225 1/8-3/4
(4.4-5.7) (3.2-19.1)
Welding
13 Welding
Typical welding parameters, for thevarious weld metal transfer modes,are documented in Table 5.Electrical polarity is direct currentelectrode positive (DCEP).
Shielding gas selection is criticalduring GMAW proceduredevelopment. Five welding gradeshielding gases are suggested forthe HASTELLOY alloys. Thosegases are 75 percent argon +25percent helium (Ar+He), 90percent helium +7.5 percent argon+2.5 percent carbon dioxide(He+Ar+CO
2), 66.1 percent argon
+33 percent helium +0.9 percentcarbon dioxide (Ar+He+CO
2), a
proprietary argon-helium-carbondioxide mixture known asNiCoBRITE™ gas, and 100percent argon (Ar).
Generally, shielding gas flow ratesare in the 35 cubic feet per hourrange. The welding torch gas cupsize is suggested to be as large aspossible. It is suggested that thewelding torch be held nearlyperpendicular to the work piece. Ifthe torch angle is held too far fromperpendicular, oxygen from theatmosphere may be drawn into theweld zone and contaminate themolten metal.
As noted in Table 5, either,Ar+He+CO
2, He+Ar+CO
2, or
NiCoBRITE shielding gasesproduces a very stable arc,excellent out-of-position
characteristics, and excellent alloy-to-carbon steel weldingcharacteristics. However, becausecarbon dioxide is present, the weldmetal surface will be highlyoxidized. This oxidized conditioncan increase the possibility of lack-of-fusion defects. It is thereforestrongly recommended thatmultipass welds, made with CO
2containing gases, be lightly groundbetween passes to remove theoxidized surface.
The use of Ar+He in the shortcircuit mode is characterized bysome spatter and some degree ofarc instability when compared towelds made with CO
2 bearing
gases. Because this shielding gasis inert, the surface is expected tobe bright and shiny with minimaloxidation. During multipasswelding, it is not mandatory togrind between passes. Thissituation also applies to the othermodes of weld metal transfer whenusing Ar+He shielding gas.
In spray transfer welding, eventhough 100 percent argonshielding gas is used, someoxidation and "soot" may be notedon the weld surface. Heavy wirebrushing and/or light grinding/conditioning (80 grit) betweenpasses is recommended.
During spray transfer welding, awater cooled welding torch isalways recommended. During
synergic welding, a water cooledtorch is recommended whenamperages exceed approximately120 amps.
As with gas tungsten arc welding,back-purging is required to ensurethe root side of the weld joint is notheavily oxidized. As an alternative,many fabricators weld withoutback-purge shielding. They thengrind the root side after welding toremove all oxidized weld metaland defects, dye penetrant checkthe weld zone, and then fill theweld joint from both sides asneeded.
It should be recognized that thefiller wire conduit liner assemblyand contact tips (parts of theGMAW welding torch) are highwear items and should beexpected to be replacedperiodically. Wear of the lineroccurs as a result of gallingbetween the carbon steel liner andthe alloy filler wire. A worn liner willcause erratic wire feed which willresult in arc instability. Somewelding torches can be fitted with anylon conduit liner. Such a linerwould be expected to reduce wearand thus increase conduit life.
It is recommended that sharpbends in the GMAW torch cable beminimized. If possible, move thewire feeder so that the torch cableis nearly straight during welding.
14Welding
Shielded Metal Arc Welding(SMAW)The shielded metal arc weldingprocess is well known for itsversatility because it can be usedin all welding positions, and in bothproduction and repair situations. Itis generally not useful on thin-sheet material. It requires nospecial equipment and can beoperated easily in remotelocations. It is strictly a manualwelding process.
Welding electrodes available fromHaynes International use lime-titania based coating formulationsand are generally classified asslightly basic to slightly acidicdepending on the particular alloy.All electrodes are classified as AC-DC, but are recommended to beused with direct current electrodepositive (DCEP) electricalcharacteristics.
All welding electrodes should bestored in a dry rod oven after thecanister has been opened. It isrecommended that the dry rodoven be maintained at about 250to 400ºF (121 to 204ºC). TheHASTELLOY B-2 and B-3 alloys
coating formulation are considereda low moisture formulation andtherefore it is mandatory that thoseelectrodes be carefully controlled.If electrodes are exposed to anuncontrolled atmosphere, they canbe reconditioned by heating in areconditioning oven at 600 to700ºF (316 to 371ºC) for 2 to 3hours.
Typical welding parameters arepresented in Table 6 for flatposition welding. For maximum arcstability and control of the moltenpuddle, it is important to maintain ashort arc length. The electrode isgenerally directed back toward themolten puddle (backhand welding)with about a 20 to 40 degree dragangle. As a general statement,stringer bead welding techniquesare recommended. Someelectrode manipulation is requiredto place the molten weld metalwhere needed. The maximummanipulation width is about threetimes the electrode core wirediameter.
Out-of-position welding isrecommended only with the 3/32inch and 1/8 inch (2.4 mm and 3.2mm) diameter electrodes. Duringout-of-position welding, the
amperage is reduced to the lowend of the range. In order to keepthe bead profile relatively flatduring vertical welding, a weavebead technique is necessary.Using 3/32 inch (2.4 mm)electrodes will reduce the weavewidth and produce flatter beads. Invertical welding, a range ofelectrode positions is possible fromforehand (up to 20 degree pushangle) to backhand welding (up to20 degree drag angle), dependingon welder preference. In over headwelding, backhand welding (dragangle 0 to 20 degrees) is required.
Starting porosity may occurbecause the electrode requires ashort time to begin generating aprotective atmosphere. This is aparticular problem withHASTELLOY B-2 and B-3 alloys.The problem can be minimized byusing a starting tab of the samealloy as the work piece or bygrinding each start to sound weldmetal. Small crater cracks mayalso occur at the stops. These canbe minimized by using a slightback-stepping motion to fill thecrater just prior to breaking the arc.It is recommended that all startsand stops be ground to soundweld metal.
TYPICAL SHIELDED METAL ARC WELDING PARAMETERS (FLAT POSITION)
Table 6
Welding CurrentElectrode ApproximateDiameter Welding Voltage Aim Rangein. (mm) Volts Amps Amps
3/32 (2.4) 22-24 65 - 70 55 - 751/8 (3.2) 22-24 90 - 100 80 - 1005/32 (4.0) 22-25 130 - 140 125 - 1503/16 (4.8) 24-26 160 - 170 150 - 180
15 Safety and Health Considerations
SAFETY AND HEALTH CONSIDERATIONSThose involved with the weldingindustry are obligated to providesafe working conditions and beaware of the potential hazardsassociated with welding fumes,gases, radiation, electricalshock, heat, eye injuries, burns,etc. Various local, municipal,state, and federal regulations(OSHA, for example) relative tothe welding and cutting pro-cesses must be considered.
Nickel-, cobalt-, and iron-basedalloy products may contain, invarying concentrations, thefollowing elemental constituents:aluminum, cobalt, chromium,copper, iron, manganese,molybdenum, nickel, and tung-sten. For specific concentrationsof these and other elementspresent, refer to the MaterialSafety Data Sheets (MSDS)H2071 and H1072 for theproduct.
The operation and maintenanceof welding and cutting equipmentshould conform to the provisionsof American National StandardANSI Z49.1, Safety in Weldingand Cutting. Attention is espe-cially called to Section 4 (Protec-tion of Personnel), Section 5(Ventilation), and Section 7(Confined Spaces) of thatdocument. Adequate ventilationis required during all welding andcutting operations. Specificrequirements are included inSection 5 for natural ventilationversus mechanical ventilationmethods. When welding inconfined spaces, ventilation shallalso be sufficient to assureadequate oxygen for life support.
The following precautionarywarning, which is supplied withall welding products, should beprovided to, and fully understoodby, all employees involved withwelding.
CautionWelding may produce fumes andgases hazardous to health.Avoid breathing these fumes andgases.
Use adequate ventilation. SeeANSI/AWS Z49.1, Safety inWelding and Cutting publishedby the American WeldingSociety.
EXPOSURES: Maintain allexposures below the limitsshown in the Material SafetyData Sheet, and the productlabel. Use industrial hygiene airmonitoring to ensure compliancewith the recommended exposurelimits. ALWAYS USE EXHAUSTVENTILATION .
RESPIRATORY PROTECTION:Be sure to use a fume respiratoror air supplied respirator whenwelding in confined spaces orwhere local exhaust or ventila-tion does not keep exposurebelow the PEL and TLV limits.
WARNING: Protect yourself andothers. Be sure the label is readand understood by the welder.FUMES and GASES can bedangerous to your health.Overexposure to fumes andgases can result in LUNGDAMAGE. ARC RAYS caninjure eyes and burn skin.ELECTRIC SHOCK can kill.
16Brazing
BRAZING
Designation Brazing TermperatureAWS AMS Composition, % 0F (0C)BAg-1 4769 45 Ag, 24 Cd, 16 Zn, 15 Cu 1145-1400 (618-760)BAg-2 4768 35 Ag, 26 Cu, 21 Zn, 18 Cd 1295-1550 (702-843)BAg-3 4771 50 Ag, 16 Cd, 15.5 Cu, 15.5 Zn, 3 Ni 1270-1500 (688-816)BAg-4 – 40 Ag, 30 Cu, 28 Zn 1435-1650 (779-899)BAg-8 – 72 Ag, 28 Cu 1435-1650 (779-899)BAu-4 – 82 Au, 18 Ni 1740-1840 (949-1004)– – 70 Au, 22 Ni, 8 Pd 1925 (1052)– – 54 Pd, 36 Ni, 10 Cu 2300 (1260)– – 36 Ni, 34 Pd, 30 Au 2175 (1191)
Table 7
SUITABLE FILLER METALS FOR USE WITH HASTELLOY ® CORROSION-RESISTANT
Brazing is defined as the joining ofmetals using a filler metal whosemelting temperature is less thanthat of the base material but over840ºF (449ºC). It is usuallycharacterized by the distribution offiller metal between closely fittedsurfaces. The filler metal thenflows with the application of heatby capillary action.
Note: The HASTELLOY alloys aretypically used in situations wheretheir corrosion resistance is ofprime consideration. Typicalbrazing alloys do not possess thesame degree of corrosionresistance. Brazing shouldtherefore only be used for joiningwhen the braze joint will beisolated from the environment.Secondly, furnace brazingoperations are typically performedin vacuum and involve a slowcooling step. Care should be takento make sure that the respectivebrazing cycle does not produceprecipitation in the HASTELLOYalloy part.
The keys to successful brazing ofHASTELLOY alloys are:1) Thorough cleaning of base-
metal surfaces.2) Proper filler metal selection for
the intended application.3) Proper fit-up and freedom of
restraint during brazing.4) Proper protective atmosphere
during brazing.5) Short heating and cooling
cycles to minimize aging.
PreparationAll forms of surface contaminationsuch as dirt, paint, ink, chemicalresidues, oxides, and scale mustbe removed from the mating partsprior to brazing. Otherwise, themolten brazing material will not"wet" and flow along the surface ofthe base material. Surfaces mustbe cleaned by solvent scrubbing ordegreasing and then bymechanical cleaning or pickling.Once cleaned, the parts should beassembled as soon as possiblewith the assembler using cleangloves to prevent subsequentcontamination.
Filler Metal SelectionSelection of filler metal dependsupon the end use of theHASTELLOY alloy being joined.For low-temperature serviceapplications, <700ºF (371ºC),silver-base brazing alloys havebeen used successfully. In hightemperature service applications,nickel-based brazing alloys aregenerally employed. Table 7shows a number of possible fillermetals for use with theHASTELLOY alloys.
Brazing alloys containing largeamoungs of copper should betreated with caution, especially ifused to braze cobalt- and iron-based alloys.
The best approach is to consultboth the brazing filler-metalmanufacturer and the basematerial manufacturer whenselecting a brazing alloy system.
17 Brazing
Proper Fit-UpProper fit-up of the parts, prior tobrazing, is just as important asprecleaning since most brazingalloys flow under the force ofcapillary action. Joint gapclearances on the order of 0.001to 0.005 inches (0.02 to 0.13mm) must be maintained at thebrazing temperature. If possible,parts should be brazed in thesolution annealed condition (i.e.,not cold worked). Excessiveexternal stresses or strainsimposed on the part duringbrazing may cause crackingproblems, especially whenbrazing fluxes are involved.
Protective AtmospheresManual torch brazing with silver-base brazing alloys invariablyrequires the application of a flux(available from the brazing alloymanufacturer). Flux protectedbrazing operations can also becarried out by using an inductioncoil heating source, or in afurnace with a reducingatmosphere.
Furnace brazing is the usualmethod of brazing HASTELLOYalloys, especially when high-temperature brazing filler metalsare employed. Nickel-basedbrazing alloys, for instance, arecommonly used in conjunction withvacuum furnaces, in high purityargon atmospheres or in hydrogen(reducing) atmospheres. The purityof the brazing atmosphere is veryimportant to ensure successfulbrazing alloy flow characteristics. Ahigh "leak rate" through a vacuumfurnace, for instance, will easilycause a thin oxide film to form onthe HASTELLOY base materialthereby impeding the flow of fillermetal.
It should be recognized that mostHASTELLOY alloys are designedto form tough oxide films whichhelp them to resist harsh serviceenvironments. These same oxidefilms will cause problems duringbrazing if atmospheres are notrigorously controlled.
Heating and Cooling CyclesThe heating and cooling timesassociated with the brazingoperation should be controlled tominimize exposure to intermediatetemperatures. The HASTELLOYcorrosion-resistant alloys tend toprecipitate secondary phaseswhen exposed in the temperaturerange of 1300 to 1850ºF (704 to1010ºC). Such secondaryprecipitation will strongly influencecorrosion resistance. In addition tothe concern about secondaryprecipitation, HASTELLOY B-2and B-3 alloys should not beexposed in the temperature rangeof 1000 to 1500ºF (538 to 816ºC)due to the possibility of loss ofductility as a result of long rangeordering. Cooling rates, in vacuumfrom elevated temperatures, canbe increased by backfilling thefurnace with argon or helium.
18Lining
CORROSION-RESISTANT LININGFigure 7
Figure 8
Metallic Lining HASTELLOY C-22 alloyLower Colorado River Authority Power Project.
Heat exchanger inlet section thin-sheet lined withHASTELLOY C-276 alloy.
The use of solid HASTELLOYcorrosion-resistant alloy isgenerally the preferred method ofconstruction. For manyapplications, however, it may bemore economical to use a steel (orlower alloy) substrate which is then
lined with a corrosion-resistantalloy. The point where lining asubstrate material becomeseconomical, as compared to solidconstruction, depends on anumber of factors which include:the corrosive environment
involved, the corrosion-resistantalloy to be used, design concerns,stresses, the complexity of thecomponent, and the particularlining method to be used.Four possible methods ofconstruction are presented whichprovide alternatives to solid alloyconstruction. Those methods are:1) Thin-sheet metallic lining.2) Clad plate construction.3) CORFACINGTM weld overlay.4) Thermal spray processes.
Thin-Sheet Metallic LiningThin-sheet metallic lining (oftenreferred to as the "WallpaperConcept") is a method of applyingthin-gage, high-performance,corrosion-resistant alloy sheet to avariety of metal substrates. Thisprocess has found wideacceptance in the ducting ofelectric power flue gasdesulfurization equipment. Atypical installation is shown inFigure 7. Such a process is equallyapplicable to many other corrosiveservice applications. Figure 8demonstrates the capability of thistechnique for protection ofchemical processing industryequipment.
19 Lining
Figure 9A
Figure 9B
The fabrication techniques areconsidered straight forward andrequire no special tools,equipment, or highly trainedpersonnel. Figure 9A shows thegeneral configuration of thisfabrication technique for flue gasdesulfurization construction. As analternative (Figure 9B), battenstrips can be applied to cover thejoints. This method is generallyused in the chemical processindustry.
Key points to consider duringfabrication include:• Lay out the installation pattern in
advance.• Develop welding parameters
and train welders in advance.• Preform sheet in shop whenever
possible.• Prepare substrate surface as
necessary.• Structually attach sheets to the
substrate.• Seal weld all-around.• Inspect and test welds for leak
tight condition.• Repair questionable areas as
necessary.
One of the important features ofthis fabrication technique is thelack of concern with substratedilution of the weld metal duringseal welding. As shown in Figure9A, all seal welding is performed inan alloy to alloy configuration.Additionally, this technique reducesfabrication time due to thesimplicity of overlapping one sheetonto another. Midsheet attachmentcan be used to insure the sheet isheld flush with the substrate and tolessen concern about damage dueto vibration.
There are several areas whereshop formed parts can save timeand effort. Edge and cornermolding can be placed
SealFillet Weld
IntermittentStructuralFillet Weld
HASTELLOYSheet
Arc Spot orPlug Weld(midsheetattachment)
0.062 in.(Nominal)
Carbon Steel orLower Alloy Substrate
®
First SheetIntermittent Fillet Welds
6 in. Center to Center Distance
Seal WeldAll-Around
Seal WeldSheet 1
Sheet 2
Sheet 3
Second Sheet
Sheet 2
Approximately 1 in. Overlap ofSecond Sheet Over First Sheet
Sheet 1
Third Sheet
Sheet 3
Sheet 1
Sheet 2
6" min. 6" min.
2t2t
2t
(1.6 mm)
(152 mm)
(152 mm)
(25.4 mm)
GENERAL WELDING AND LAYOUT CONFIGURATION
20Lining
Figure 10A Figure 10B
Figure 10C
Alloy Sheet
PerformedEdgeMolding
Substrate
Seal Weld
IntermittentFillet Welds
Alloy Sheet
Alloy Sheet
AlloySheet
PerformedCornerMolding
Substrate
SealWeld
IntermittentFillet Welds
AlloySheet
AlloySheet
Seal WeldSeam
90° Break
Midsheet Attachment (If Specified)
Substrate
Seal Weld
Intermittent Fillet Welds
Alloy Sheet
Seal Weld
21 Lining
Induced draft fan thin-sheet lined with HASTELLOY C-276 alloy.
Figure 11
Figure 10D
over the intersection of wall sheetsto form a sealed joint as shown inFigures 10A and 10B. Preformedsheets with one or two edges bent90 degrees can be fitted onto theceiling or floor as shown in Figure10C. Finally, preformed sheetswith prepunched holes (Figure10D) can be used to form anexpansion joint seal.
While this method of lining doesnot produce a metallurgical bondbetween the alloy lining and thesubstrate, the process doesproduce equipment with excellentmechanical properties. Figure 11shows a large fan which was builtfrom carbon steel and then linedwith HASTELLOY C-276 alloy.This fan rotates at high speed andhas not suffered any mechanicaldifficulties in service. Detailedinformation concerning thin-sheetmetallic lining can be found inHaynes publication H-2037.
Sheet 90° BreakBolt Holes Pre-Punched
No Welding RequiredDown Length of Joint
Expansion Joint
Assembly View
Substrate
Alloy Sheet
22Lining
Complete the first layer of HASTELLOY alloy weld metal as shownabove.
Figure 12A
Grind back the HASTELLOY alloy adjacent to the weld to avoidmelting the alloy while welding the steel. Prepare the joint asshown above and complete the steel weld.
Figure 12B
Figure 12C
Figure 12D
Complete the second layer of HASTELLOY alloy weld metal asshown above.
Complete the third layer of HASTELLOY alloy weld metal asshown above. Use a fourth layer of alloy weld metal if necessary.
Clad Plate ConstructionTwo types of clad plate areavailable for the HASTELLOYalloys. Hot-roll bonded plate andexplosion bonded plate have bothbeen used to fabricate corrosion-resistant components. The natureof the equipment to be fabricatedwill dictate the manufacturing routefor the plate which would beacceptable.
Hot-Roll Bonded PlateIn projects, such as flue gasdesulfurization ductwork, wherelarge plates are required with atotal thickness less than 0.375 inch(9.5 mm) and an alloy thickness ofapproximately 0.062 inch (1.6mm), hot-roll bonded plate canoffer an appropriate alternative tothe thin-sheet metallic lining. Sinceannealing is required to obtain thebest corrosion resistance in thealloy material, the backing steelsare usually limited to very lowcarbon grade materials. Thisallows for annealing and waterquenching of the hot-roll bondedplate without producing a brittlesteel backer. Mechanicalproperties of this product will reflectthe combined properties of thealloy and the low carbon steel.
Fabrication, of components fromthis product, is generallyaccomplished by welding with fillermetal which matches thecomposition of the alloy sheet.Overalloyed filler metal may beused if localized attack isexpected, such as in a flue gasdesulfurization environment.
Explosive Bonded PlateFor the construction of chemicalprocess equipment, explosivebonded plate is the predominantsource of the material. Thisprocess allows the use of thetraditional grades of high strengthsteels for vessel fabrication.
Alloy
1/16 in.3/8 in.
Steel WeldSteel
Second BeadFirst BeadLast Bead
Step 1
Alloy
Steel WeldSteel
Step 2
Alloy
Steel WeldSteel
Step 3
Alloy
Steel WeldSteel
Step 4
23 Lining
625 AlloyTwo Layers Deposit
75 mils per year
Figure 13
HASTELLOY C-22 AlloyOne Layer Deposit
4 mils per year
0.045 in. Crevice Depth Attack No Crevice Attack
10% Ferric Chloride1040F (400C) - 120 Hours
Conventional techniques can beused to fabricate equipment fromthe clad plate. The tube holes oftube-sheets usually have thegrooves machined so that at leastone is located in the cladding andthe balance are in the basematerials.
Care must be taken during weldfabrication to avoid dilution of thecladding alloy by the basematerial. Figures 12A thru 12Dillustrate the suggested method forjoining clad plates.
After preparation of the weldangles, the alloy is ground backslightly on either side of the jointand below the base metal surface(Figure 12A). The root weld ismade and the base metal jointcompleted from the back side(Figure 12A). The first layer of alloyfiller is deposited on the joint usinga practice that will minimizedilution. This layer may be groundto a uniform thickness to helpcontrol dilution of the next layer(Figure 12B). Two additional layersof alloy are then deposited tocomplete the joint (Figures 12C &12D). During all welding operationsthe interpass temperature shouldbe maintained below 200ºF(93ºC).
During explosion-bonding, theexplosive force produces a zoneadjacent to the bond line thatcontains considerable colddeformation. Presence of this coldwork can accelerate aging of someof the alloys during certainsubsequent stress-relieving heattreatments for the carbon steel.
HASTELLOY B-2 and B-3 alloysshould not be explosive bonded.Results have been inconsistentwith a high risk of crackingduring the bonding process.
CORFACINGTM Weld OverlayWeld overlay cladding, using high-performance, corrosion-resistantalloys is an accepted alternative tosolid alloy construction for manyapplications. Weld overlaycladding of tube sheets and oflarge diameter shafts are commonapplications. In both cases, theheavy section carbon steelsubstrate components aresurfaced with a relatively thin layerof corrosion-resistant alloy. Asecond area where weld overlaycladding is used is in the localrepair and refurbishment ofchemical process components. Inthis case, the substrate is probablynot carbon steel.
It is important to recognize,however, that the corrosionresistance of a weld overlaydeposit is not equivalent to thewrought base material, of similarcomposition. Several factorsstrongly influence the corrosion-resistance of a weld overlaydeposit. By far the most importantcontrollable factor is substrate(base metal) dilution. A secondfactor, which affects all weld metaldeposits, is alloying elementsegregation.
Base metal dilution is the meltingand mixing of the substrate withthe corrosion-resistant weldoverlay filler material. As substratebase material is mixed with thealloy filler metal, the iron content ofweld overlay deposit increases.This increase in iron contentlowers (dilutes) the total content ofthe critical elements (chromium,molybdenum, tungsten) of a high-performance alloy system. Thisincrease in iron, coupled with thelowering of other alloyingelements, leads to lower weldoverlay corrosion resistance.Welding techniques must,therefore, be employed whichminimize base metal dilution.
The most common method toovercome base metal dilution is touse multiple weld layers. As ageneral rule, a three layer deposit,even with relatively high basemetal dilution, will approach thefiller wire composition. With carefulcontrol of welding parameters, atwo layer deposit may approachfiller wire composition.
24Lining
Approx. Approx.Wire Welding TravelDiameter Shielding Flow Rate Current Approx. Speedin. (mm) Gas ft.3/hr. Amps Volts in./min.
Globular Transfer0.045 (1.1) 100% Argon 50 170-180 26-28 6.8*Technique: Mechanical weave 5/8 in. wide, minimum dwell, 100 cycles/minutes, 200ºF (max.) interpass temperature.
GAS METAL ARC WELD OVERLAY PROCESS (FLAT POSITION)*Table 8
Dilution can be controlled by usingwelding processes that have lowpenetration patterns. For example,gas metal arc welding in theglobular and short-arc transfermodes have lower penetrationpatterns when compared to thespray transfer mode. In addition,oscillation of the welding torch willlower penetration (dilution). Finally,bead placement affects totalsubstrate dilution. In some cases,gas metal arc welding (short-arcmode) beads are overlapped insuch a way that part of the weldpenetration is in the previous alloyweld bead, rather than in thesubstrate base material.
Welding parameters which havebeen shown to give low basemetal dilution are provided in Table8. In this case, a low penetration
welding process is coupled withwelding torch oscillation. Such aprocess would be expected toproduce dilution under ten percentin a two layer deposit.
Figure 13 illustrates gas metal arcwelding in the short-arc modewhere bead overlap was used tocontrol dilution. BecauseHASTELLOY C-22 alloy hasinherently higher crevice corrosionresistance, when compared to 625alloy, a one layer C-22 welddeposit has significantly lowercorrosion attack when comparedto a two layer 625 deposit.
Additional information concerningweld overlaying with HASTELLOYC-22 filler material can be found inTechnical Brochure H-2054,CORFACING Weld Overlays withHASTELLOY C-22 alloy.
Thermal Spray ProcessesCorrosion protection by nonfusionwelding processes (i.e., thermalspray techniques) has been donesuccessfully. Use of theseprocesses has received increasedattention by the pulp and paperand power utility industries as amethod of refurbishing digesterinteriors and boiler tubes.However, it should be recognizedthat most thermal spray methodsdo not achieve a 100 percentdense deposit and are usually onlymechanically bonded to thesubstrate.
Thin coatings, offering someprotection, can be made byplasma spray (powders), wireflame spray and by electric-arcspraying (wire), however it is not arecommended practice foraqueous corrosion service.
25 Hot Working
HOT WORKINGHASTELLOY corrosion-resistantalloys are readily hot worked into avariety of shapes and productforms. However, these alloys aresomewhat more sensitive to strainand strain rates than are typicalaustenitic stainless steels. The hotworking temperature ranges forthese alloys tend to be narrow.Care must be exercised during hotworking to achieve satisfactoryresults.
The characteristics ofHASTELLOY alloys that must beconsidered during hot workinginclude relatively low meltingtemperatures, high hot strength,high strain rate sensitivity, lowthermal conductivity, and relativelyhigh strain hardening coefficients.Furthermore, the strength of thesealloys increases rapidly as thetemperature decreases in the hotworking range.
Because of these factors, relativelymoderate reductions per pass andfrequent reheating operations givethe best results. Also, relativelyslow hot deformation processing
tends to achieve better results,because lower forces are requiredand the heat buildup due toworking is kept within reasonablelimits.
ForgingThe following are generalguidelines to follow in forgingHASTELLOY corrosion-resistantalloys:
• Soak billets or ingots at least 1/2hour at forging temperature foreach inch of thickness. The useof a calibrated optical pyrometeris essential.
• The stock should be turnedfrequently to present the coolerside to the furnace atmosphere.Direct flame impingement on thealloy must be avoided.
• Forging should beginimmediately after withdrawalfrom the furnace. A short timelapse may allow surfacetemperature to drop as much as100 to 200ºF (38 to 93ºC). Donot raise the forging temperature
to compensate for heat loss, asthis may cause incipient melting.
• Moderately heavy reductions (25to 40 percent) are beneficial tomaintain as much internal heatas possible, thus minimizinggrain coarsening and thenumber of reheatings.Reductions greater than 40percent per pass should beavoided.
• Do not make radical changes inthe cross sectional shape, suchas going from a square directlyto a round, during initial formingstages. Instead go from squareto round cornered square tooctagon to round.
• Condition (remove) any cracksor tears developed duringforging. Very often this can bedone at intermediate stagesbetween forging sessions.
• The temperature rangesrecommended for forgingHASTELLOY alloys are shownin Table 9.
26Hot Working
FORGING TEMPERATURES
Table 9
Forging TemperatureStart* Finish**
Alloy 0F (0C) 0F (0C)
HASTELLOY® B-2 alloy 2250 (1232) 1800 (982)HASTELLOY B-3 alloy 2250 (1232) 1800 (982)HASTELLOY C-4 alloy 2150 (1177) 1750 (954)HASTELLOY C-22 alloy 2250 (1232) 1750 (954)HASTELLOY C-276 alloy 2250 (1232) 1750 (954)HASTELLOY C-2000 alloy 2250 (1232) 1750 (954)HASTELLOY G-30 alloy 2100 (1149) 1700 (927)HASTELLOY N alloy 2200 (1204) 1600 (871)*Maximum**Depends on nature and degree of working.
Hot RollingHot rolling of HASTELLOY alloyscan be performed to produce anyconventional rolled forms. Theconsiderations listed above forforging generally apply to hotrolling also. Moderate reductionsper pass (15 to 20 percentreduction in area) and rollingspeeds of 200 to 300 surface feetper minute tend to give goodresults without overloading the mill.
Frequent reheatings are usuallyrequired to keep the temperatureof the work piece in the hotworking range. Because of the lowthermal conductivity and thesomewhat sluggish minor phasedissolution kinetics associated withthese alloys, it is good practice tosoak the work piece thoroughly atthe hot working temperaturebefore rolling.
Hot UpsettingHASTELLOY alloys can be hotupset when the length of the partto be upset is no greater thanabout three times the diameter.Care should be taken to ensurethat the temperature of the pieceto be upset is in the upper end ofthe forging temperature range.
Impact ExtrusionParts such as engine valves,pump rotors, jet engine bolting,and gears can be produced fromHASTELLOY alloys by impactextrusion. Impact extrusion iscarried out at the solution heat-treating temperature so that thealloy is forged in its most plasticstate. Accurate temperaturecontrol and maintenance of auniform temperature throughoutthe work piece are essential.Restrikes should be avoided.
Hot FormingThe forming of plate intocomponents such as dished heads
is normally done by cold pressingor spinning with intermediateanneals. However sometimes thesize and thickness of materialrequires that hot forming beutilized. When this is required, thefurnace temperature is usually setat an intermediate temperaturebetween that suggested forannealing (Heat Treatmentsection, Table 10) and lowerforging temperature (Table 9).Temperature during hot workshould not be less than the finishforging temperature. Reheat asnecessary to maintain the propertemperature. Dies should bewarmed so that excessive chillingof the surface does not occur.
AnnealingFollowing any hot workingoperations, HASTELLOY alloysshould be reannealed for optimumcorrosion resistance. Annealingtechniques are detailed in the HeatTreatment section (Table 10) ofthis brochure.
27 Cold Working
COLD WORKINGFigure 14Cold working is the preferable
method of forming theHASTELLOY corrosion-resistantalloys. Since they are generallystiffer than the austenitic stainlesssteels, more energy is requiredduring cold forming. In addition,these alloys tend to work hardenmore readily than do the austeniticstainless steels. Depending on theseverity of deformation, they mayrequire a number of intermediateforming stages to produce the finalpart. Figure 14 shows the effect ofcold work on the hardness of theHASTELLOY alloys. A curve fortype 304 stainless steel has beenincluded for comparison.
Generally, mill annealed sheet hassufficient ductility for mild formingwithout the need for subsequentheat treatment. Generally, thepresence of cold work does noteffect either the uniform or pittingcorrosion resistance of theHASTELLOY corrosion-resistantalloys. The presence of heavy colddeformation can increase thestress corrosion crackingsusceptibility in certainenvironments. Annealingcomponents with deformationgreater than about 7 to 10 percentouter fiber elongation will reducethat susceptibility.
For more severe cold deformation,where cracking is possible due toreduction in ductility, a series ofsuccessive forming operations arerecommended, each followed byan intermediate anneal. Undermost conditions, intermediateannealing should be performed atthe recommended solutionannealing temperature. It is highlydesirable to remove scale from thepart prior to the next formingoperation either by pickling ormechanical means. A final solutionanneal is recommended after suchsuccessive intermediate cold work/annealing operations.
Care should be taken to avoid a"critical cold reduction" of about 2to 10 percent, if solution annealingis specified. Under theseconditions, abnormal grain growthis possible which can lead to a
surface condition often referred toas "orange peel" or "alligator hidesurface."
Cold formed components withresidual tensile stresses, inconjunction with the possibility ofintermediate temperatureembrittlement, caused byexposure at intermediatetemperatures for critical periods oftime, have been observed toproduce intergranular crackingduring the heat treatment ofHASTELLOY B-2 alloy. It has beenobserved that shot peening theknuckle radius and straight flangeregions of a cold-formed head,prior to heat treatment, can helpreduce intermediate temperatureintergranular cracking of B-2 alloyby lowering the tensile residualstress patterns at the surface ofthe cold formed component.
In the case of cold formed headsof HASTELLOY B-2 or B-3alloys, a solution annealedshould be done whendeformation is greater than 7%outer fiber elongation of coldwork. Without the anneal thesealloys are very susceptable tocracking at welds and heataffected zones duringsubsequent fabrication. Thecracking may not becomeobvious until the unit has been
put into service.HASTELLOY B-3 alloy is moreresistant to heat treat crackingthan B-2 alloy. In any event,annealing of cold formedcomponents (>7% outer fiberelongation) is required and careshould be taken to use wellcontrolled furnaces (fast heat-uprate, good temperature control,and rapid cool down rate).
Lubrication is a significantconsideration for successfully coldworking these alloys. Althoughlubrication is seldom required for asimple "U" bend on a brake press,heavy duty lubricants are requiredfor cold drawing. Mild formingoperations can be successfullycompleted by using a lard oil orcastor oil, which are easilyremoved. More severe formingoperations require metallic soaps,or chlorinated or sulfochlorinatedoils. NOTE: When the sulfo-chlorinated oils are used, the workpiece must be carefully cleaned ina degreaser or alkaline cleaner.
Lubricants that contain white lead,zinc compounds, or molybdenumdisulfide are not recommendedbecause they are difficult toremove prior to the final anneal.Also, lead, zinc, and sulfur tend toembrittle these alloys. Care shouldbe taken to remove die material,lubricants, or other foreign
450
400
350
300
250
200
150
100
0 10 20 30 40 50 60
C-276C-22
C-4G-30
304SS
B-2/B-3
Percent Cold Work
Vick
ers
Har
dne
ss N
umb
er
EFFECT OF COLD WORK ON HARDNESS
28Cold Working
materials from the part beforeannealing as many of theseproducts can affect the mechanicaland corrosion properties of thealloys.
Tube FormingHASTELLOY corrosion-resistantalloys can readily be formed coldin standard pipe and tube bendingequipment. The minimumrecommended bending radiusfrom the radius point to thecenterline of the tube is three timesthe tube diameter for most bendingoperations. When measured fromcenterline to centerline of the"hairpin" straight legs, it is six timesthe tube diameter (see Figure 15).Under special circumstances (tubediameter and wall thickness), theminimum bending radius can bereduced to twice the tube diameter.
Figure 15Minimum Bending Radius
As the ratio of tube diameter towall thickness increases, the needfor internal and external supportbecomes increasingly important inorder to prevent distortion. If toosmall a bending radius is used,wrinkles, poor ovality, and bucklingcan occur in addition to thinning.When forming tubing for heatexchangers, a minimum of threeinches should be added to the totaldeveloped length of each tube
before bending. This additionallength is necessary to allow formismatch of the ends after formingand for trimming the ends of thetubes for stuffing the tube bundle.Heating during forming is notrecommended, nor is stressrelieving of the tubes after coldforming because of the possibleformation of precipitates thatdecrease the corrosion resistance.If the corrosion application issevere or if stress relieving isrequired, annealing the entire tubeshould be done as described in theHeat Treatment section of thisbrochure.
SpinningSpinning is a deformation processof forming sheet metal or tubinginto seamless hollow cylinders,cone hemispheres, or othersymmetrical circular shapes by acombination of rotation and force.There are two basic forms knownas manual spinning and power orshear spinning. In the formermethod no appreciable thinning ofmetal occurs, whereas in the latter,metal is thinned as a result ofshear forces.
Nearly all HASTELLOY corrosion-resistant alloys can be spinformed, generally at roomtemperature. The control of qualityincluding freedom from wrinklesand scratches as well asdimensional accuracy is largelydependent on operator skill. Theprimary parameters that should beconsidered when spinning thesealloys are:• Speed• Feed Rate• Lubrication• Material• Strain Hardening Characteristics• Tool Material, Design and Surface Finish• Power of the Machine
The minimum speeds normallyemployed are about 200 surfacefeet per minute but generally lowspeeds are seldom used exceptfor spinning small diameter workpieces. Speeds of 400 to 1500surface feet per minute are mostwidely used. The feed ratesnormally used are 0.010 to 0.080inches per revolution. Feed rate isimportant since it controls the workpiece finish. To find the optimumcombination of speed, feed, andpressure, a few pieces should bespun experimentally when a "newjob" is set up. During continuousoperation, the temperature of themandrel and spinning tool changesmay necessitate the adjustment ofpressure, speed, and feed toobtain uniform results.
Lubrication should be used in allspinning operations. The usualpractice is to apply lubricant to theblank prior to loading in themachine. It may be necessary toadd lubricants during operation.During spinning, the work pieceand tools should be flooded with acoolant such as an emulsion ofsoluble oil in water. Sulfurized orchlorinated lubricants should notbe used since the operation ofspinning may burnish the lubricantinto the surface.
In cone spinning, metaldeformation is such that forming isin accordance with the sine law.This law states that the wallthickness of the starting blank andthat of the finished work piece arerelated as:
t2 = t1Sin αwhere t
1= thickness of
starting blankwhere t2 = thickness of
spun piecewhere a = one half the
apex angle ofcone
6Dr=3DD
r=Minimum Bending RadiusD=Tube Diameter
29 Cold Working
When spinning cones with smallangles (less than 35 degreesincluding angle), the best practiceis to use more than one spinningpass with a different cone angle foreach pass. HASTELLOY alloyscan be reduced 30 to 50 percentbetween process annealsdepending on the material and itsstrain hardening characteristics.
The tool material and work piecedesign and surface finish are veryimportant in achieving a trouble-free operation. Mandrels used inspinning must be hard, wearresistant, and resistant to fatigueresulting from normal eccentricloading. Finish of mandrels shouldbe no rougher than 50microinches, preferably 15 to 32microinches. The variousdiameters should be trueconcentric with each other.
Power spinning is a severe, coldworking operation which markedlyincreases the ultimate and yieldstrengths of the alloy. In manyapplications, this increase is highlydesirable, but for someapplications the spun piece shouldsubsequently be annealeddepending on the alloy and theservice environment.
Drop HammeringHASTELLOY corrosion-resistantalloys can be formed by using thesame techniques that are used instainless steel drop-hammeroperations. Annealing is essential ifthe depth of the draw is severe.Particular care should be taken toremove all foreign material fromthe part before annealing.
PunchingPunching is usually performedcold. Perforation should be limitedto a minimum diameter of twice thegage thickness. The center-to-center dimension should beapproximately three to four timesthe hole diameters. The punch todie clearances per side are:
ShearingBecause of the toughness of thesealloys, compared to carbon steelsand austenitic stainless steels,shearing equipment with greaterpower is required. For example, ascissor type shear capable ofshearing 3/8 inch (9.5 mm) thickmild carbon steel could be used toshear HASTELLOY alloys up to 1/4 (6.4 mm) inch thick. Generally,HASTELLOY alloys 3/8 inch (9.5mm) or less in thickness aresheared and thicknesses above 3/8 inch (6.4 mm) are abrasive sawcut or plasma arc cut.
Cold rolled and annealed sheetUp to 1/8 in. (3.2 mm) incl. 3-5% of sheet thicknessHot rolled and annealed sheetOver 1/8 in. (3.2 mm) 5-10% of sheet thickness
30Heat Treatment
Temperature* Type ofAlloy 0F (0C) Quench
HASTELLOY® B-2 alloy 1950 (1066) WQ or RACHASTELLOY B-3 alloy 1950 (1066) WQ or RACHASTELLOY C-4 alloy 1950 (1066) WQ or RACHASTELLOY C-22 alloy 2050 (1121) WQ or RACHASTELLOY C-2000 alloy 2075 (1135) WQ or RACHASTELLOY C-276 alloy 2050 (1121) WQ or RACHASTELLOY G-30 alloy 2150 (1177) WQ or RACHASTELLOY N alloy 2150 (1177) WQ or RACWQ=water quench.RAC=rapid air cool.*± 25 deg. F.
HEAT TREATMENT
HEAT-TREATING TEMPERATURESTable 10
Wrought products of HASTELLOYalloys are supplied in the mill-annealed condition unlessotherwise specified. This annealingprocedure has been designed toplace the material in the optimumcondition with respect tomechanical properties andcorrosion resistance. Following allhot-forming operations, a reannealof the material should always bedone to restore those properties.
Annealing is often performed aftercold working operations to restoreductility and lower the yield andultimate tensile properties.Generally, annealing is notrequired if the cold work is belowseven percent outer fiberelongation.
In general, the only heat treatmentthat is acceptable for these alloysis a full solution anneal. Stressrelief temperatures commonlyused for steels, stainless steels,and some other nickel-basedalloys are not effective for thesealloys. If the heat treatment is doneat an intermediate temperature,high enough to actually relieve thestresses, it may also promotesome precipitation that could bedetrimental to corrosion resistance.
Annealing may be performed toreduce residual stresses whichcan play a role in stress corrosioncracking resistance. It is generallyheld that stresses above 7 to 10percent outer fiber elongation cancause increased stress corrosioncracking in some environments.
Because of the very low carboncontents or stabilizing elements,welded wrought HASTELLOYcorrosion-resistant alloys do notrequire heat treatment afterwelding. Annealing can be used toincrease the corrosion resistanceof the weld fusion zone.
Before heat treatment, makeabsolutely sure that grease,graphite, and other foreignmaterials are removed from allsurfaces. Carburization of thesematerials at the heat-treatingtemperatures can reduce corrosionresistance. Proper control oftemperature and time cycle arealso important. Table 10 lists theproper heat-treating temperaturesand type of quench.
31 Heat Treatment
Holding TimeAn inflexible set of rules governingsoaking-annealing time is notfeasible because of the manyvariations in types of furnaces,furnace operation, facilities forloading and unloading the furnace,etc. Temperature should bemeasured with a thermocoupleattached to the piece beingannealed. The actual holding timeshould be measured starting whenthe "entire section" is at thespecified annealing temperature. Itis important to remember that thecenter of a section does not reachthe solutioning temperature assoon as the surface.
Normally, hold time is specified inthe range of 10 to 30 minutesdepending on section thickness.Thin-sheet components are held atthe shorter time, while heaviersections are held at the longertimes. The effect of cold workingthat result from stamping, deepdrawing, bending, etc. can beeliminated by holding a minimumof 5 to 10 minutes, depending ongage size, at the solutionannealing temperature.
QuenchingRapid cooling is essential aftersolution heat treatment to preventthe precipitation of secondaryphases and the resultant loweringof the corrosion resistance of thesealloys. Water quenching isrecommended on material thickerthan 3/8 inch (9.5 mm). Rapid aircooling can be used on sections
thinner than 3/8 inch (9.5 mm),however, water quenching ispreferred. The time from thefurnace to the quench tank or tothe start of rapid air cooling, mustbe as short as possible (less thanthree minutes).
HASTELLOY B-2 alloyThe method of annealingHASTELLOY B-2 alloy isdemanding and the following itemsshould be considered verycarefully. Extended exposure in anintermediate temperature range of1100 to 1500ºF (593 to 816ºC),especially for cold work conditionmaterial, can cause intergranularcracking.
The following steps are designedto minimize intermediatetemperature cracking ofHASTELLOY B-2 alloy.• Furnace must be at the
annealing temperature. Thethermal capacity of the furnaceshould be large to insure a quickrecovery of furnace temperature.
• It has been observed that shotpeening the knuckle radius andstraight flange regions of a cold-formed head, prior to heattreatment, can help reduceintermediate temperatureintergranular cracking, ofHASTELLOY B-2 alloy bylowering the tensile residualstress patterns at the surface ofthe cold formed component.
The improved thermal stability ofHASTELLOY B-3 alloy
minimized the problemsassociated with fabrication ofB-2 alloy components. This isdue to the reduced tendency toprecipitate deleteriousintermetallic phases in B-3 alloy,thereby, affording it greaterductility than B-2 alloy duringand following various thermalcycling conditions. Neverthelessfor heavy section weldments orfor those weldmentscharacterized by high residualwelding stresses, fabricatorsmay wish to follow the heat treatrequirements recommended forB-2 alloy.
Shot PeeningCold formed components withresidual tensile stresses, exposedat intermediate temperatures forcritical periods of time, have beenobserved to produce intergranularcracking during the heat treatmentof HASTELLOY B-2 alloy. It hasbeen observed that shot peeningthe knuckle radius and straightflange regions of a cold-formedhead, prior to heat treatment, canhelp reduce intermediatetemperature, intergranular crackingof B-2 alloy by lowering the tensileresidual stress patterns at thesurface of the cold formedcomponent.
HASTELLOY B-3 alloy is lesssensitive to the above issues,however, the same methods forB-2 alloy should be used toeliminate the risk of cracking ofB-3 alloy.
32Descaling and Pickling
Sulfuric- Nitric-Hydrochloric Hydrofluoric
VIRGO Descaling Water Acid Bath Acid Bath WaterSalt Bath Rinse 1650F 125-1600F Rinse
Time Time, (740C) (52-710C) Time,Alloy Temp. min. min. Time, min. Time, min. min.
B-2, B-3 8000F 1-3 1-2 25-45 – 3(4270C) (Steam spray)
C-276, C-4, C-2000, 9700F 1-3 1-2 3 25 3C-22, G-30, N (5210C) (Steam spray)
DESCALING AND PICKLING
VIRGO DESCALING SALT BATH
Table 11
Sulfuric- Permanganate- Nitric- Nitric-Hydrochloric Sodium Hydrochloric Hydrofluoric
Sodium Acid Bath Hydroxide Bath Acid Bath Acid BathHydride Bath* 1650F 135-1550F 1650F 125-1600F
Time (740C) (57-680C) (740C) (52-710C) WaterAlloy Temp. min. Time, min.* Time, min.* Time, min.* Time, min.* Rinse
B-2, B-3 750-8000F 15-20 20-30 20-30 20-30 1 max. Steam(399-4270C) spray
C-276, C-4, 750-8000F 15 – 15 – 15 DipC-2000, C-22, (399-4270C)G-30,N*Followed by a water rinse.
SODIUM HYDRIDE (REDUCING SALT BATH) PROCESS
Table 12
Because of their inherent corrosionresistance, HASTELLOY alloysare relatively inert to cold acidpickling solutions. After heattreatment, the oxide film is moreadherent than that of stainlesssteels. Molten caustic bathsfollowed by acid pickling are themost effective descaling methods.Baths of VIRGO descaling salt,sodium hydride (DuPont), or DGSoxidizing salt have been usedeffectively.
Tables 11, 12 and 13 providepickling media, temperatures andtimes for each method. Thecompositions of the picklingsolutions are listed in Table 14.Sand, shot, or vapor blasting areacceptable for removing scaleunder certain conditions. Theblasting material should be suchthat it provides for a rapid cuttingaction rather than smearing thesurface. Sand should not bereused especially if contaminated
with iron. After blasting, it isdesirable to give the part an acidpickle to remove any imbeddediron or other impurities. Extremecare should be taken when sandblasting thin-gage parts because ofthe danger of distortion and ofembedding sand or scale in themetal surface. Sand blasting alsotends to work harden the metal'ssurface.
33 Descaling and Pickling
Nitric-HydrofluoricDGS Oxidizing Salt Bath Acid Bath
Time Water 130-1500F (54-660C)Alloy Temp. min. Rinse Time, min. Water Rinse
B-2, B-3 850-9500F 2-7 Dip 1-4 Dip and(454-5100C) steam spray
C-276, C-4, C-2000 850-9500F 2-7 Dip 10-20 Dip andC-22, G-30, N (454-5100C) steam spray
DGS OXIDIZING SALT BATH PROCESS
Table 13
Composition of Pickling Solution, Percent by WeightDescaling Sulfuric-Hydrochloric Permanganate-Sodium Nitric-HydrofluoricMethod Acid Bath Hydroxide Bath Acid Bath
VIRGO 15-17% sulfuric acid Not used 7-8% nitric acidDescaling 0.5-1.0% hydrochloric acid 3-4% hydrofluoric acidSalt BathSodium 15-17% sulfuric acid 4-6% potassium 8-12% nitric acidHydride 0.5-10% hydrochloric acid permanganate 2-3% hydrofluoric acidProcess (used only for B-2 alloy) 1-2% sodium hydroxideDGS (Oxidizing Not used Not used 15-25% nitric acidSalt Bath) 3-5% hydrofluoric acidProcess
COMPOSITION OF PICKLING SOLUTIONS
Table 14
34Grinding and Machining
GRINDING AND MACHINING
Type of Grinding Wheels* Manufacturer Type of Work CoolantCylinder GrindingStraight or Tapered 53A80-J8V127 Norton Sharp corners and Heavy dutyO.D.'s fine finish soluble coolant 25:1 mix
CASTROL 653Form Work, Single Wheel 38A60-J8-VBE Norton Removing stock DrySection Method Sharp corner work
Straight radius workForm Work, Crush-Roll 53A220-L9VB Norton Precision forms Straight oilMethod RadiusCenterless 53A80-J8VCN Norton Thin-walled material Heavy duty
Solid or heavy- soluble coolant 25:1 mixwalled material CASTROL 653
Internal GrindingStraight or Tapered 23A54-L8VBE Norton Small holes Heavy duty
Medium-size holes soluble coolant 25:1 mixLarge holes CASTROL 709Small counterbores
Surface GrindingStraight Wheel 32A46-H8VBE Norton Dry or any heavy duty
38A46-I-V Norton soluble coolant 25:1 mixCASTROL 653
Double Opposed Disk 87A46-G12-BV Gardner Through-feed work Heavy dutyType 87A46-J11-BW Gardner Ferris wheel work soluble coolant 10:1 mix
Thin work CASTROL 653Cylinder or Segmental 32A46-F12VBE Norton Thin work, bevels Sal-soda in waterType and close CASTROL 653
tolerance workSingle Wheel Section 32A46-F12VBEP Norton Profile work DryMethodThread GrindingExternal Threads A100-T9BH Norton VANTOL 5299-M
or equivalentHoningInternal C120-E12-V32 Bay State VANTROL 5299-C
C220-K4VE Carborundum or equivalentJ45-J57 Sunnen
Rough GrindingCut-off (Wet) 86A461-LB25W Norton CASTROL 653Cut-off (Dry) 4NZA24-TB65N Norton DrySnagging 4ZF1634-Q5B38 Norton Dry*The wheels indicated have been optimized for speeds between 6000 and 6500 sfpm.
GRINDING OF HASTELLOY ALLOYS
Table 15
When very close tolerances arerequired, grinding is
recommended for finishingHASTELLOY alloys.
Recommended wheels andcoolants are listed in Table 15.
35 Grinding and Machining
MACHINING
RECOMMENDED TOOL TYPES AND MACHINING CONDITIONS
Table 16
Operations Carbide Tools
Roughing, with C-2 or C-3 grade: Negative rake square insert, 450 SCEA1, 1/32 in. nose radius.severe interruptions; Tool holder: 50 neg. back rake, 50 neg. side rake.Turning or Facing Speed: 30-50 sfm, 0.004-0.008 in. feed, 0.150 in. depth of cut.
Dry2, oil3, or water-base coolant4.Normal roughing; C-2 or C-3 grade: Negative rake square insert, 450 SCEA, 1/32 in. nose radius.Turning or Facing Tool holder: 50 neg. back rake, 50 neg. side rake.
Speed: 90 sfm depending on rigidity of set up, 0.010 in. feed,0.150 in. depth of cut.
Dry, oil, or water-base coolant.Finishing; C-2 or C-3 grade: Positive rake square insert, if possible, 450 SCEA,Turning or Facing 1/32 in. nose radius.
Tool holder: 50 pos. back rake, 50 pos. side rake.Speed: 95-110 sfm, 0.005-0.007 in. feed, 0.040 in. depth of cut.Dry or water-base coolant.
Rough Boring C-2 or C-3 grade: If insert type boring bar, use standard positive rake toolswith largest possible SCEA and 1/16 in. nose radius. If brazed tool bar,grind 00 back rake, 100 pos. side rake, 1/32 in. nose radius and largestpossible SCEA.
Speed: 70 sfm depending on the rigidity of setup, 0.005-0.008 in. feed,1/8 in. depth of cut.
Dry, oil, or water-base coolant.Finish Boring C-2 or C-3 grade: Use standard positive rake tools on insert type bars. Grind
brazed tools as for finish turning and facing except back rake maybe best at 00.
Speed: 95-110 sfm, 0.002-0.004 in. feed.Water-base coolant.
NOTES: 1 SCEA – Side cutting edge angle or lead angle of the tool.2 At any point where dry cutting is recommended, an air jet directed on the tool may provide substantial tool life increases. A water-base coolant mist may also be effective.3 Oil coolant should be a premium quality, sulfochlorinated oil with extreme pressure additives. A viscosity at 1000F from 50 to 125 SSU.4 Water-base coolant should be premium quality, sulfochlorinated water soluble oil or chemical emulsion with extreme pressure additives. Dilute with water to make 15:1
mix. Water-base coolant may cause chipping and rapid failure of carbide tools in interrupted cuts.
HASTELLOY corrosion-resistantalloys are classified as moderateto difficult when machining,however, it should be emphasizedthat these alloys can be machinedusing conventional productionmethods at satisfactory rates.During machining these alloyswork harden rapidly, generate highheat during cutting, weld to thecutting tool surface, and offer highresistance to metal removalbecause of their high shearstrengths. The following are keypoints which should be consideredduring machining operations:• CAPACITY - Machine should
be rigid and overpowered asmuch as possible.
• RIGIDITY - Work piece andtool should be held rigid.Minimize tool overhang.
• TOOL SHARPNESS - Makesure tools are sharp at alltimes. Change to sharpenedtools at regular intervalsrather than out of necessity. A0.015 inch (0.4 mm) wearland is considered a dull tool.
• TOOLS - Use positive rakeangle tools for most machin-ing operations. Negative rakeangle tools can be consideredfor intermittent cuts and heavystock removal. Carbide-tippedtools are suggested for mostapplications. High speed toolscan be used, with lowerproduction rates, and are
often recommended forintermittent cuts.
• POSITIVE CUTS - Use heavy,constant, feeds to maintainpositive cutting action. If feedslows and the tool dwells inthe cut, work hardeningoccurs, tool life deterioratesand close tolerances areimpossible.
• LUBRICATION - lubricantsare desirable, soluble oils arerecommended, especiallywhen using carbide tooling.
Detailed machining parametersare presented in Tables 16 and17. General plasma cuttingrecommendations are presentedin Table 18.
36Grinding and Machining
RECOMMENDED TOOL TYPES AND MACHINING CONDITIONSTable 17
Operations High Speed Steel Tools Carbide ToolsFacing Milling M-2, M-7, or M-40 series5: Radial and Carbide not generally successful,
axial rake 00-pos. 100, 450 C-grade may work. Use positive axialcorner angle, 100 relief angle. and radial rake, 450 corner angle,
Speed: 20-30 sfm. 100 relief angle.Feed: 0.003-0.005 in. Speed: 50-60 sfm.Oil6 or water-base coolant7. Feed: 0.005-0.008 in.
Oil or water-base coolants will reducethermal shock damage of carbidecutter teeth.
End Milling M-40 series or T-15: If possible, Not recommended, but C-2 grades mayuse short mills with be successful on good setups.4 or more flutes for rigidity. Use positive rake.
Speed: 20-25 sfm. Speed: 50-60 sfm.Feed: 0.002 in. tooth 1/4 in. dia. Feed: Same as high speed steel.
0.002 in. tooth 1/2 in. dia. Oil or water-base coolants will reduce0.003 in. tooth 3/4 in. dia. thermal shock damage.0.004 in. tooth 1 in. dia.
Oil or water-base coolant.Drilling M-33, M-40 series or T-15: Use short C-2 grade not recommended, but tipped
drills, heavy web, 1350 crank-shaft, drills may be successful on rigidgrind points wherever possible. setup if no great depth. The web
Speed: 10-15 sfm. must be thinned to reduce thrust.Feed: 0.001 in. rev. 1/8 in. dia. Use 1350 included angle on point.
0.002 in. rev. 1/4 in. dia. Gun drill can be used.0.003 in. rev. 1/2 in. dia. Speed: 50 sfm.0.005 in. rev. 3/4 in. dia. Oil or water-base coolant.0.007 in. rev. 1 in. dia. Coolant-feed carbide tipped drills
Oil or water-base coolant may be economical in some setups.Use coolant feed drills if possible.
Reaming M-33, M-40 series or T-15: Use 450 C-2 or C-3 grade: Tipped reamerscorner angle, narrow primary recommended, solid carbideland and 100 relief angle. reamers require very good
Speed: 10-20 sfm. setup. Tool geometry sameFeed: 0.003 in. tooth 1/2 in. dia. as high speed steel.
0.008 in. tooth 2 in. dia. Speed: 50 sfm.Oil or water-base coolant. Feed: Same as high speed steel.
Tapping M-1, M-7, M-10: 2 flute, spiral point, Not recommendedplug tap 00-100 hook anglenitrided surface may be helpfulby increasing wear resistancebut may cause chippingor breakage. Tap drill for 60-65%thread, if possible, to increasetool life.
Speed: 7 sfm (cutting).Use best possible tapping compound.
sulfochlorinated oil base preferred.
Electrical HASTELLOY alloys can be easily cut using any conventional electrical dischargeDischarge machining system (EDM) or wire EDM.Machining
NOTES: 5 M-40 series High Speed Steels include M-41, M-42, M-43, M-44, M-45 and M-46 at the time of writing. Others may be added and should be equally suitable.
6 Oil coolant should be a premium quality, sulfochlorinated oil with extreme pressure additives. A viscosity at 1000F from 50 to 125 SSU.
7 Water-base coolant should be premium quality, sulfochlorinated water soluble oil or chemical emulsion with extreme pressure additives. Dilute with water to make 15:1 mix.
Table 18
Plasma Arc HASTELLOY® alloys can be cut using any conventional plasma arc cutting system.Cutting The best arc quality is achieved using a mixture of argon and hydrogen gases.
Nitrogen gas can be substituted for hydrogen gases, but the cut quality will deteriorateslightly. Shop air or any oxygen bearing gases should be avoided whenplasma cutting the HASTELLOY alloys.
37 Selected Data and Information
APPENDIX–SELECTED DATA AND INFORMATION
NOMINAL CHEMICAL COMPOSITIONS, PERCENT 1
Table A-1
Alloy Ni Co Cr Mo W Fe Si Mn C Others
HASTELLOY® 69a 1* 1* 28 – 2* 0.1* 1* 0.01* –B-2 alloy
HASTELLOY 65b 3* 1.5 28.5 3* 1.5 0.1* 3* 0.01* Al-0.5*B-3 alloy Ti-0.2*
HASTELLOY 65a 2* 16 16 – 3* 0.08* 1* 0.01* Ti-0.7*C-4 alloy
HASTELLOY 59a 2* 23 16 – 3* 0.08* – 0.01* Cu-1.6C-2000 alloy
HASTELLOY 56a 2.5* 22 13 3 3 0.08* 0.5* 0.01* V-0.35*C-22 alloy
HASTELLOY 57a 2.5* 16 16 4 5 0.08* 1* 0.01* V-0.35*C-276 alloy
HASTELLOY 43a 2* 30 5.5 2.5 15 1* 1.5* 0.03* Cb-0.8*G-30 alloy Cu-2*
HASTELLOY 71a 0.2* 7 16 0.5* 5* 1* 0.8* 0.08* Al+Ti-0.5*N alloy Cu-0.35*
HASTELLOY 63a 2.5* 5 24 – 6 1* 1* 0.12* V-0.6*W alloy1 The undiluted deposited chemical composition of covered electrodes of some of these alloys may vary beyond the limits shown.*Maximum a As Balance b Minimum
38Selected Data and Information
AVAILABLE FORMSTable A-2
WELDING WIRE AND COVERED ELECTRODE SIZES
Table A-3
APPLICABLE ASME AND AWS SPECIFICATIONS
Table A-4
Form Alloy Available Sizes, in.*
Loose Coils1 B-2, C-4, C-22, C-2000, 3/16, 5/32, 1/8, 3/32,C-276, G-30, W 1/16, 0.045, 0.035
Layer Wound Coils2 B-2, C-4, C-22, C-2000, 1/16, 0.045, 0.035C-276, G-30, W
Cut Lengths3 B-2, C-4, C-22, C-2000, 3/16, 5/32, 1/8, 3/32,C-276, G-30, W 1/16, 0.045, 0.035
Covered Electrodes B-2, C-4**, C-22, C-2000, 3/16, 5/32, 1/8, 3/32, 5/64C-276, G-30, W
* Not all sizes shown are stocked.** Not available in 3/16 in. electrodes.1 Packaged in 25, 50, and 100 lb. coils. Diameters 3/32 in. and smaller may be sold in minimum quantities of 10 lb.2 Packaged in 25, 50, and 100 lb. coils. Diameters 1/8 in. and larger are on 24.5 in. x 4.25 in. cardboard rims and diameters less than 1/8 in.
are on 12 in. x 3 in. wide flanged disposable spools.3 Standard 36 in. cut lengths in 5, 10, and 25 lb. packages. Other lengths available on request.
Weld Filler MetalBase Plate/ Round Bar Bare CoveredMetal Sheet/ to 3 1/2 in. Welded Seamless Welded AWS A 5.14 AWS A 5.11
Alloy UNS No. Strip (89 mm) Dia. Pipe Tubing Tubing ASME SFA 5.14 ASME SFA 5.11ASME ASME ASME ASME ASME
B-2 N10665 SB-333 SB-335 SB-619 SB-622 SB-626 ERNiMo-7 ENiMo-7
B-3 N10675 SB-333 SB-335 SB-619 SS-622 SB-626 ERNiMo-10 ENiMo-10
C-276 N10276 SB-575 SB-574 SB-619 SB-622 SB-626 ERNiCrMo-4 ENiCrMo-4
C-2000N06200 SB-575 SB-574 SB-619 SB-622 SB-626 ERNiCrMo-17 ENiCrMo-17
C-4 N06455 SB-575 SB-574 SB-619 SB-622 SB-626 ERNiCrMo-7 ENiCrMo-7
C-22 N06022 SB-575 SB-574 SB-619 SB-622 SB-626 ERNiCrMo-10 ENiCrMo-10
G-30 N06030 SB-582 SB-581 SB-619 SB-622 SB-626 ERNiCrMo-11 ENiCrMo-11
N N10003 SB-434 SB-573 – – – ERNiMo-2 –
W N10004 – – – – – ERNiMo-3 ENiMo-3
Sheetand Covered
Alloy Strip Plate Bar Wire Billet Electrodes Tubing Pipe
HASTELLOY® B-2 alloy X X X X X X X XHASTELLOY B-3 alloy X X X X X X X XHASTELLOY C-276 alloy X X X X X X X XHASTELLOY C-2000 alloy X X X X X X X XHASTELLOY C-4 alloy X X X X X X X XHASTELLOY C-22 alloy X X X X X X X XHASTELLOY G-30 alloy X X X X X X X XHASTELLOY N alloy X X X – X – X XHASTELLOY W alloy – – X X – X – –
39 Selected Data and Information
COMPARATIVE AVERAGE PROPERTIES DATA AT ROOM TEMPERATURE*Table A-5
YieldUltimate StrengthTensile at 0.2% Elongation
Density Strength offset in 2 in. RockwellAlloy lb./in3 Ksi MPa Ksi MPa % HardnessHASTELLOY® B-2 alloy 0.333 132.5 914 57.5 396 55 B-98HASTELLOY B-3 alloy 0.333 128.3 885 58.3 400 58 B-98HASTELLOY C-276 alloy 0.321 114.9 790 51.6 355 61 B-90HASTELLOY C-2000 alloy 0.307 113.0 777 55.0 378 62 B-88HASTELLOY C-4 alloy 0.312 114.8 789 58.1 400 54 B-92HASTELLOY C-22 alloy 0.314 115.0 791 56.5 389 59 B-90HASTELLOY G-30 alloy 0.297 100.0 688 47.0 323 56 B-88HASTELLOY N alloy 0.320 115.1 792 45.5 313 51 B-96*Sheet heat-treated in accordance with Table 10 page 30.
THERMAL EXPANSION
Table A-6
British Units Metric UnitsTemp., Microinches/ Temp.,
Alloy 0F in.-0F 0C µm/m-k
HASTELLOY® B-2 alloy 68-600 6.2 20-316 11.2HASTELLOY B-3 alloy 78-600 6.3 25-300 11.4HASTELLOY C-276 alloy 75-600 7.1 24-316 12.8HASTELLOY C-2000 alloy 77-600 7.0 25-300 12.6HASTELLOY C-22 alloy 68-600 7.0 20-316 12.6HASTELLOY C-4 alloy 68-600 7.0 20-316 12.6HASTELLOY G-30 alloy 86-600 8.0 30-316 14.4HASTELLOY N alloy 70-600 6.8 21-316 12.3HASTELLOY W alloy 73-300 6.3 23-50 11.4
THERMAL CONDUCTIVITY
Table A-7
British Units Metric UnitsTemp., Btu-in./ft2- Temp.,
Alloy 0F in.-0F 0C W/m-K
HASTELLOY® B-2 alloy 572 102 300 14.6HASTELLOY B-3 alloy 600 104 300 14.8HASTELLOY C-276 alloy 600 104 316 15.0HASTELLOY C-2000 alloy 600 99 300 14.1HASTELLOY C-4 alloy 572 104 300 15.0HASTELLOY C-22 alloy 572 108 300 15.5HASTELLOY G-30 alloy 572 116 300 16.7HASTELLOY N alloy 572 100 300 14.4
40
B-2, B-3®, C-4, C-22®, C-276, C-2000®, D-205™, G-3, G-30®, G-35™, G-50®, and N
ULTIMET®
25, R-41, 75, HR-120®, HR-160®, 188, 214™, 230®, 230-W™, 242™, 263, 556™, 617, 625, 65SQ®, 718,X-750, MULTIMET®, and Waspaloy
Ti-3Al-2.5V
HASTELLOY Family of Heat-Resistant Alloys
HASTELLOY ® Family of Corrosion-Resistant Alloys
S, W, and X
HAYNES ® Family of Heat-Resistant Alloys
HAYNES Titanium Alloy Tubular
Bar, Billet, Plate, Sheet, Strip, Coils, Seamless or Welded Pipe & Tubing, Pipe Fittings, Flanges,Fittings, Welding Wire, and Coated Electrodes
Standard Forms:
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