ASTM A249 TP321 S32100: Chemistry Composition and Mechanical Properties

ASTM A249/ASME SA249 Standard Specification for Welded Austenitic Steel Boiler, Superheater, Heat-Exchanger, and Condenser Tubes

Standard: ASTM A249, ASME SA249

Material: TP321, S32100 Equivalent Material: 12Ch18N10T X6CrNiTi18-10, 1.4541

Chemistry Composition

C, % Si, % Mn, % P, % S, % Cr, % Ni, % Ti, % 0.08 max 1.00 max 2.00 max 0.045 max 0.030 max 17.0-19.0 9.0-12.0 5*(C+N)-0.7

Mechanical Properties

Tensile Strength , MPa Yield Strength, MPa Elongation, % Hardness, HRB 515 min 205 min 35 min 90 max

Properties of Stainless Steel - Grade 316, 316L

SX 316 / 316L Technical Data

 Summary

SX 316 is an improved version of SX 304, with the addition of molybdenum and a slightly higher nickel content. The resultant composition of SX 316 gives the steel much increased corrosion resistance in many aggressive environments.  The molybdenum makes the steel more resistant to pitting and crevice corrosion in chloride-contaminated media, sea water and acetic acid vapours.   The lower rate of general corrosion in mildly corrosive environments gives the steel good atmospheric corrosion resistance in polluted marine atmospheres.
SX 316 offers higher strength and better creep resistance at higher temperatures than SX 304.  SX 316 also possesses excellent mechanical and corrosion properties at sub-zero temperatures.  When there is a danger of corrosion in the heat-affected zones of weldments, the low-carbon variety SX 316L should be used.  SX 316 Ti, the titanium-stabilised version, is used for its resistance to sensitization during prolonged exposure in the 550^oC-800^oC temperature range.

 

Typical Applications

Because of its superior corrosion and oxidation resistance, good mechanical properties and fabricability, SX 316 has applications in many sectors of industry.  Some of these include:
Tanks and storage vessels for corrosive liquids.
Specialised process equipment in the chemical, food, paper, mining, pharmaceutical and petroleum industries.
Architectural applications in highly corrosive environments.

Chemical Composition (ASTM A 240)
 

	C	Mn	P	S	Si	Cr	Ni	Mo	Ti
SX316 SX316L SX316Ti	0.08 max 0.03 max 0.08 max	2.0 max	0.045 max	0.030 max	1.0 max	16.0 to 18.0	10.0 to 14.0	2.00 to 3.00	- 0.5 max 5X%C

Typical properties in the annealed condition
The properties quoted in this publication are typical of mill products and unless indicated must not be regarded as guaranteed minimum values for specification purposes.

1. Mechanical properties at room temperature
 

	SX316		SX316L		SX316Ti
	Typical	Minimum	Typical	Minimum	Typical	Minimum
Tensile Strength, MPa	580	515	570	485	600	515
Proof Stress (0.2 % offset), MPa	310	205	300	170	320	205
Elongation (Percent in L = 5.65 So)	55	40	60	40	50	40
Hardness (Brinell)	165	-	165	-	165	-
Erichsen Cup Test Value mm	8 - 10	-	10 - 11	-	-	-
Endurance (fatigue) limit, MPa	260	-	260	-	260	-

2. Properties at elevated temperatures
The values given refer to SX 316 and SX 316 Ti only as strength values for SX 316L fall rapidly above 425^oC.

Short Time Elevated Temperature Tensile Strength

Temperature, C	600	700	800	900	1000
Strength, MPa	460	320	190	120	70

Creep data
Stress for a creep rate of 1% in 10 000 h

Temperature, oC	550	600	650	700	800
Stress, MPa	160	120	90	60	20

Recommended Maximum Service Temperature
(Oxidising conditions)

Continuous Service            925^oC
Intermittent Service             870^oC

3. Properties at Sub-Zero Temperatures
( SX 316 )
 

Temperature	oC	-78	-161	-196
Proof Strength (0.2% Offset)	MPa	400	460	580
Tensile Strength	MPa	820	1150	1300
Impact Strength (Charpy V-Notch)	J	180	165	155

4. Corrosion Resistance

4.1    Aqueous
         For specific conditions, consult VRN technical staff.  As a rough guide, the following examples are given
         for pure acid-water mixtures.
 

TemperatureoC	20	80
Concentration, (-% by mass)	10       20       40       60       80       100	10       20       40       60       80       100
Sulphuric Acid	0          1         2         2         1          0	2          2         2        2         2         2
Nitric Acid	0          0         0         0         0          1	0          0         0        0         1         2
Phosphoric Acid	0          0         0         0         1          2	0          0         0        0         1         2
Formic Acid	0          0         0         1         1          0	0          0         1        1         1         0

 Key:         0 = resistant    -    corrosion rate less than 100 mm/year
                 1 = partly resistant    -    corrosion rate 100 m to 1000 mm/year
                2 = non resistant    - corrosion rate more than 1000 mm/year
 

4.2    Atmospheric
          The performance of SX 316 compared with other metals in various environments is shown in the
          following table.  Corrosion rate is based on a 5 year exposure.
 

Environment	Corrosion Rate (mm/year)
	SX 316	Aluminium-3S	Mild Steel
Rural	0.0025	0.025	5.8
Marine	0.0076	0.432	34.0
Marine-Industrial	0.0051	0.686	46.2

Note:  For corrosion resistance of SX 316 relative to other types, see the section in Comparative Data.

4.3    Thermal Processing

4.3.1 Annealing. Heat from 1 010^oC to 1 120^oC and cool rapidly in air or water.  The best corrosion
          resistance is obtained when the final annealing temperature is above 1 070^oC.

4.3.2 Stress relieving.  Heat from 200 - 400^oC and air cool.

4.3.3 Hot working
          Initial forging and pressing:                                    1150  - 1200^oC
          Finishing temperature:                                            above 900^oC
          For upsetting operations, forgings
          should be finished between:                                   930 and 980^oC
          All hot working operations should be followed by annealing.

Note:  Soaking times to ensure uniformity of temperature are up to 12  times that required for the same thickness of mild steel.

Cold Working

SX 316 / 316L, being extremely tough and ductile, can be readily fabricated by cold working. Typical operations include bending, forming, deep drawing and upsetting.

Source: www.fanagalo.co.za

PROPERTY OF STAINLESS STEEL ASTM A321

Chemical Formula

Fe, <0.08% C, 17-19% Cr, 9-12% Ni, <2% Mn, <1% Si, 0.3-0.7% Ti, <0.045% P, <0.03% S

Background

Grades 321 and 347 are the basic austenitic 18/8 steel (Grade 304) stabilised by Titanium (321) or Niobium (347) additions. These grades are used because they are not sensitive to intergranular corrosion after heating within the carbide precipitation range of 425-850°C. Grade 321 is the grade of choice for applications in the temperature range of up to about 900°C, combining high strength, resistance to scaling and phase stability with resistance to subsequent aqueous corrosion.

Grade 321H is a modification of 321 with a higher carbon content, to provide improved high temperature strength.

A limitation with 321 is that titanium does not transfer well across a high temperature arc, so is not recommended as a welding consumable. In this case grade 347 is preferred - the niobium performs the same carbide stabilisation task but can be transferred across a welding arc. Grade 347 is therefore the standard consumable for welding 321. Grade 347 is only occasionally used as parent plate material.

Like other austenitic grades, 321 and 347 have excellent forming and welding characteristics, are readily brake or roll formed and have outstanding welding characteristics. Post-weld annealing is not required. They also have excellent toughness, even down to cryogenic temperatures. Grade 321 does not polish well, so is not recommended for decorative applications.

Grade 304L is more readily available in most product forms, and so is generally used in preference to 321 if the requirement is simply for resistance to intergranular corrosion after welding. However 304L has lower hot strength than 321 and so is not the best choice if the requirement is resistance to an operating environment over about 500°C.

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BS 2S130D (BRIGHT) CHEMICAL COMPOSITION, APPLICATION AND MACHINABILITY

Stainless Steel Bar. British Standard aerospace grade. Moderate strength niobium stabilised steel (347 type) with moderate corrosion resistance. For aerospace and defence components.

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BS 5S80D; AISI 431; UNS S43100 in ASTM A276; AMS 5628: chemical composition, application and machinability

Stainless Steel Bar. British Standard aerospace grade. Good strength 431 type steel with fair corrosion resistance. For aerospace and defence components.

RELATED SPECIFICATIONS:

AISI 431; UNS S43100 in ASTM A276; AMS 5628; BS 5S80D

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ASTM A 564 Gr.XM-12, UNS S15500, AMS 5659 (15/5 PH VAR/ESR): chemical composition, application and machinability

Precipitation Hardening Stainless Steel Bar. American aerospace grade, vacuum arc remelted or electro-slag refined (type XM-12). High strength/toughness with good corrosion resistance. For aircraft/missile construction, chemical process equipment and nuclear reactor components

RELATED SPECIFICATIONS: 
ASTM A 564 Gr.XM-12, UNS S15500, AMS 5659 (15/5 PH VAR/ESR) 
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ASTM A276-98b, AISI 440C Stainless Steel Data Sheet: Composition, Applications and Properties

440C Stainless Steel Data Sheet

440C stainless steel is a martensitic grade of stainless steel that provides very good wear resistance combined with moderate corrosion resistance in mild environments. 440C is heat treatable to RC 59. This grade is commonly used in cutlery and food processing applications.
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440C Stainless steel is a type of modern steel and famous for its high corrosion resistant, wear resistance, strength and hardness qualities among all the stainless alloys, capable of attaining (after heat treatment) the highest hardness (60 HRC). It has good resistance to the atmosphere, fresh water and mild acids. It has best resistance in the hardened, tempered and passivated condition. It allows creating a smooth polished surface and Razor sharp edges. It is being used in cutting instruments, rolling element bearings, valve seats, high quality knife blades, surgical instruments, chisels, ball bearings and valve parts and most commonly used in the production of Cutting tools, including Haircutting Scissors, daggers and swords.

Grades 440A and 440B are identical except for slightly lower carbon contents (0.60 - 0.75% and 0.75 - 0.95% respectively), they attain lower hardness but slightly higher corrosion resistances. Although all three versions of this grade are standard grades, in practice 440C is more available than the A or B variants.

Another alloy 440F (UNS S44020) also exists, with the same high carbon content as 440C.

440C Related Specifications

USA	Germany	Japan	Australia
ASTM A276-98b 440C SAE 51440C, AISI 440C UNS S44004	W.Nr 1.4125 X105CrMo17	JIS G4303 SuS 440C	AS 2837-1986 440C

Germany: DIN 1.4125
United States: AMS 5618 , AMS 5630 , ASTM A276 , ASTM A314 , ASTM A473 , ASTM A493 , ASTM A580 , FED QQ-S-763 , MIL SPEC MIL-S-862 , SAE 51440C , SAE J405 (51440C) , UNS S44004

Chemical Composition

Carbon	1.00%
Manganese	.50%
Chromium	17.50%
Silicon	.35%
Molybdenum	.50%

Chemical Composition ranges of 440C stainless steel

Grade440C
Ingredients	Min.	Max.
Carbon	0.95	1.20
Manganese	-	1.00
Silicon	-	1.00
Phosphorus	-	0.040
Sulphur	-	0.030
Chromium	16.00	18.00
Molybdenum	-	0.75
Iron	Balance

 

Typical Applications

Plastic Injection Molds

Cutlery

Custom Knives

Food Processing Equipment

Bearings

Petroleum Pumps and Valves

Surgical Tools

Corrosion Resistance

440C stainless steel is characterised by good corrosion resistance in mild domestic and industrial environments, including fresh water, organic materials, mild acids, various petroleum products. 440C also provides extreme high strength, hardness and wear resistance when in the hardened and tempered condition.

Thermal Treatments

Preheat : Optional preheat stage for unbalanced geometries or complex designs - 1100/1250F (590/675C), equalize, standard preheat stage - 1400/1500F (760/815C), equalize.

Austenize : 1850/1900F (1010/1020C), equalize, 30/45 minutes at temperature.

Quench : Air, positive pressure vacuum to below 125F (50C)(2 bar minimum). Interrupted oil to below 1000F (540C). Air cool to 150F (65C). Temper immediately.

Temper : 400/800F (205/425C), hold 2 hours at temperature, air cool. Temper twice. Avoid tempering between 800 and 1100F, due to a decrease in toughness and corrosion resistance.

Cryogenic Treating : Refrigeration treatments may improve long term dimensional stability by transforming retained austenite. Refrigeration treatments should generally be performed after the first temper, and must be followed by a temper.

Hardness and Impact Toughness Data
Air cooled from 1885F(1030C)

Tempering
Temperature		Hardness
Deg. F	Deg. C	HRC
As quenched		59
212	100	59
400	205	56
600	315	54
800	425	55
1000	540	51

Surface Treatments

Nitriding decreases the corrosion resistance of stainless steels and is generally not recommended for stainless steels.

Annealing

A. Heat to 1650F (870C), hold 2 hours, slow cool 25F (15C)/hour maximum) to 1200F (650C), air cool.
OR
B. Heat to 1600F (870C), hold 2 hours, cool to 1300F (760C), hold 4 hours, air cool.
Typical annealed hardness: 215/255 BHN.

Stress Relieving

Annealed Material: Heat to 1200/1250F(650/675C), hold two hours, cool in still air.
Hardened Material: Heat to 25F(15C) below original tempering temperature, hold two hours, cool in still air.

Welding

Use 440C or 420 stainless steel filler material. Annealed Material: Preheat 600/800F(320/430C), maintain over 600F(320C) during welding. Reanneal or temper 1200/1400F(650/760C) for 4 hours after welding.

Hardened Material: Preheat to 50F(30C) below original tempering temperature (400F (205C) minimum). Maintain above 400F(205C) during welding. Cool to 150F(65C) after welding. Temper immediately 25F(15C) below original tempering temperature. Minimum 400F(205C)

Physical Properties

Modulus of Elasticity	30psix10(6)	(200 GPa)
Density	0.278 lb/in3	(7640 kg/M3)
Thermal Conductivity	14.0 BTU/hr./ft./F	24.2 W/m/ °K)

440C Physical Properties
Physical properties for grade 440 stainless steels.

Grade	Density (kg/m3)	Elastic Modulus (GPa)	Mean Coefficient of Thermal Expansion (mm/m/C)			Thermal Conductivity (W/m.K)		Specific Heat 0-100C (J/kg.K)	Electrical Resistivity (nW.m)
			0-100C	0-200C	0-600C	at 100C	at 500C
440A/B/C	7650	200	10.1	10.3	11.7	24.2	-	460	600

 Machining
In the annealed condition this grade is relatively easily machined; approximately the same as for high speed steel. If this grade is hardened machining becomes very difficult and probably impossible.

Source:  http://www.multiplex-trd.com/articles/about_440c_steel.htm
             http://www.simplytoolsteel.com/440C-stainless-steel.html

UNS S13800-AMS 5629 (13/8 PH VAR)- ASTM A564 XM-13: chemical composition, application and machinability

Precipitation Hardening Stainless Steel Bar. American aerospace grade, vacuum arc remelted (type XM-13). Very high strength/toughness with good corrosion resistance. For aircraft structural components and use in petrochemical industry.
RELATED SPECIFICATIONS
UNS S13800
AMS 5629 (13/8 PH VAR)
ASTM A564 XM-13
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UNS S31254 - ASTM A182 F44: chemical composition, application and machinability

Super Duplex Stainless Steel. 25% chromium copper-free super duplex (austenitic/ferritic) steel (also known as SAF 2507). Good strength/ductility combined with high marine corrosion resistance. Primarily for Oil & Gas and marine applications.
Specifications:
UNS S31254 - ASTM A182 F44
EN 10088-3 1.4547 (Grade X1CrNiMoN20-18-7)
NORSOK MDS R11 to R15, R17 & R18
NACE MR01-75/ ISO 15156
 

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ASTM A 351/A 351M: Chemical Composition, Tensile Properties

ASTM A351 / A351M

This specification covers austenitic steel castings for valves, flanges, fittings, and other pressure-containing parts. The steel shall be made by the electric furnace process with or without separate refining such as argon-oxygen decarburization. All castings shall receive heat treatment followed by quench in water or rapid cool by other means as noted. The steel shall conform to both chemical composition and tensile property requirements.

Keywords: austenitic stainless steel; duplex stainless steel; pressure containing parts; stainless steel; steel castings.

Tensile Properties

(ASTM Standard)

ASTM A-747 CB-7Cu-1: COMPOSITION APPLICATION, WELDABILITY AND PROPERTIES

 DESCRIPTION

CB-7Cu-1 is a precipitation hardening, martensitic stainless steel, known in the wrought form as 17-4PH. Resistance to atmospheric corrosion, organic compounds, sea water and paper mill liquors is intermediate between that of the hardenable CA alloys and the non-hardenable CF alloy grades. The alloy is particularly suited to service combining corrosion resistance and high strength at temperatures up to 700oF. Machining is frequently conducted on castings in the solution annealed condition, followed by hardening at a low temperature thus alleviating distortion and scaling. Service at temperatures below -40oF should be avoided due to poor impact properties at this temperature.

COMPOSITION

	C	Mn	Si	Cr	Ni	P	S	Cu(i)	Nb(ii)	N2
Min %				15.5	3.6			2.5	0.20
Max %	0.07	0.7	1.0	17.7	4.6	0.035	0.03	3.2	0.35	0.05

Notes: (i) Copper should be less than 3% if the castings require welding.

           (ii) Niobium should be omitted if the castings are hardened at 900oF

APPLICATIONS

Centrifuge components, food mixers and processing machinery, pump and compressor impellers, pump shafts and sleeves, screw conveyors,valve bodies and trim, propeller shafts,and hydraulic cylinders 

PRODUCT FORMS

Horizontal and vertical centrifugal castings; static castings.

PHYSICAL PROPERTIES

Density (lbs/in3)	0.280
Liquidus(oF)	2750
Thermal Conductivity (Btu/h/ft2/ft/oF)	9.9 @ 212oF 11.3 @ 500oF 13.0 @ 860oF 13.1 @ 900oF

		Aged at 900oF	Aged at 1100oF
Thermal Expansion (10-6in/in oF)	70-200oF 70-400oF 70-600oF 70-800oF	6.0 6.1 6.3 6.5	6.6 6.9 7.1 7.2

Magnetic Permeability            Ferromagnetic

MECHANICAL PROPERTIES

WELDABILITY

CB-Cu7-1 may be welded by the SMAW, GTAW or GMAW processes.

Electrodes	Same composition or 308
Preheat	Not required for section less than 0.75" thick. Heavier sections with substantial
welding may be preheated to 500oF.
Post weld heat treatment	900 to 1100oF, Air Cool.

RELATED SPECIFICATIONS

ASTM: A747(CB7Cu-1 and CB7Cu-2).

Nearest wrought grade: 17-4PH, 15-5PH.

Source: Kobuta steel datasheet