ASTM A182 F304/ A182 F304L Welding Neck Flange

China ASTM A182 F304/ A182 F304L Welding Neck Flange, Find details about China ASTM A182 F304 Flange, ASTM A182 F304L Flange from ASTM A182 F304/ A182 F304L Welding Neck Flange

Basic Info.

Model NO.

WELDING NECK

Manufacturing Way

Forging

Ndividual Drawing

Welcome

Trademark

Transport Package

Pallet/Wooden Case

Specification

asme B16.5

Origin

China

HS Code

73072100

Model NO.

WELDING NECK

Manufacturing Way

Forging

Ndividual Drawing

Welcome

Trademark

Transport Package

Pallet/Wooden Case

Specification

asme B16.5

Origin

China

HS Code

73072100

Product Desciption

Austenitic Stainless Steel
Austenitic steels are the most popular grades of stainless steels because of their ductility, ease of working and good corrosion resistance and are very commonly used in manufacture of piping components. Austenitic steels are non-magnetic and non-hardenable by heat treatment, however they can be hardened by cold working. The most commonly used stainless steel grades are Type 304, Type 316 and Type 321.
Stainless steel grades with suffix L have low carbon content. The low carbon content provides good weldability and good corrosion resistance after welding, however they have lower strength than the grades with higher carbon content. The dual certified grades of stainless steel are commonly used in the industry such as SS 304/304L or SS 316/316L. For e.g. the SS 304/304L dual certified grade has lower carbon content similar to SS 304L grade but higher mechanical strength of SS 304 grade.
Type 304 grade contains approximately 18% Chromium and 8% Nickel.
Effect of carbon on corrosion resistance
The lower carbon variants (316L) were established as alternatives to the standards (316) carbon range grade to overcome the risk of intercrystalline corrosion (weld decay), which was identified as a problem in the early days of the application of these steels. This can result if the steel is held in a temperature range 450 to 850°C for periods of several minutes, depending on the temperature and subsequently exposed to aggressive corrosive environments. Corrosion then takes place next to grain boundaries.
If the carbon level is below 0.030% then this intercrystalline corrosion does not take place following exposure to these temperatures, especially for the sort of times normally experienced in the heat affected zone of welds in thick sections of steel.
Effect of carbon level on weldability
There is a view that the low carbon types are easier to weld than the standard carbon types.
There does not seem to be a clear reason for this and the differences are probably associated with the lower strength of the low carbon type. The low carbon type may be easier to shape and form, which in turn may also affect the levels of residual stress left the steel after is forming and fitting up for welding. This may result in the standard carbon types needing more force to hold them in position once fitted-up for welding, with more of a tendency to spring-back if not properly held in place.
The welding consumables for both types are based on a low carbon composition, to avoid intercrystalline corrosion risk in the solidified weld nugget or from the diffusion of carbon into the parent (surrounding) metal.
Dual-certification of low carbon composition steels
Commercially produced steels, using current steelmaking methods, are often produced as the low carbon type as a matter of course due to the improved control in modern steelmaking. Consequently finished steel products are often offered to the market dual certified to both grade designations as they can then be used for fabrications specifying either grade, within a particular standard.

A/SA182 F304 / 304L Technical Data

Summary
304 is the most versatile and the most widely used of all stainless steels. Its chemical composition, mechanical properties, weldability and corrosion/oxidation resistance provide the best all-round performance stainless steel at relatively low cost. It also has excellent low temperature properties and responds well to hardening by cold working. If intergranular corrosion in the heat affected zone may occur, it is suggested that 304L be used.
Typical Applications
304 is used in all industrial, commercial and domestic fields because of its good corrosion and heat resisting properties. Some applications include:
Tanks and containers for a large variety of liquids and solids.
Process equipment in the mining, chemical, cryogenic, food, dairy and pharmaceutical industries.
Chemical Composition (ASTM/ASME A/SA182)

A/SA182	C	Mn	P	S	Si	Cr	Ni
304 304L	0.08 max 0.03 max	2.0 max	0.045 max	0.030 max	1.0 max	18.0 to 20.0	8.0 to 11 8.0 - 12.0

Typical Properties in the Annealed Condition
The properties quoted in this publication are typical of mill production and unless indicated should not be regarded as guaranteed minimum values for specification purposes.
1. Mechanical Properties at Room Temperature

	304		304L
	Typical	Minimum	Typical	Minimum
Tensile Strength, MPa	600	515	590	485
Proof Strength, (Offset 0.2 %), MPa	310	205	310	170
Elongation (Percent in 50mm)	60	40	60	40
Hardness (Brinell)	170	-	170	-
Endurance (fatigue) limit, MPa	240	-	240	-

2. Properties at elevated temperatures
All these values refer to 304 only.
304L values are not given because its strength decreases markedly above 425^oC.

Time Elevated Temperature Tensile Strength

Temperature, ^oC	600	700	800	900	1000
Tensile Strength, MPa	380	270	170	90	50

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

Temperature, ^oC	550	600	650	700	800
Stress, MPa	120	80	50	30	10

Maximum Recommended Service Temperature
(Oxidising Conditions)
Continuous Service            925^oC
Intermittent Service             850^oC
3. Properties at Sub-Zero Temperatures
    ( 304 / 304L )

Temperature	^oC	-78	-161	-196
Tensile Strength	MPa	1100/950	1450/1200	1600/1350
Proof Stress (Offset 0.2%)	MPa	300/180	380/220	400/220
Impact Strength (Charpy V-Notch)	J	180/175	160/160	155/150

4. Corrosion Resistance
Aqueous
As a rough guide the following examples are given for certain pure acid-water mixtures-

Temperature ^oC	20	80
Concentration, % by mass	10 20 40 60 80 100	10 20 40 60 80 100
Sulphuric Acid	2 2 2 2 1 0	2 2 2 2 2 2
Nitric Acid	0 0 0 0 2 0	0 0 0 0 1 2
Phosphoric Acid	0 0 0 0 0 2	0 0 0 0 1 2
Formic Acid	0 0 0 0 0 0	0 1 2 2 1 0

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

4.2 Atmospheric
The performance of 304 compared with other metals in various environments is shown in the following table. The corrosion rates are based on a 10 year exposure.

Environment	Corrosion Rate (mm/year)
Environment	SX 304	Aluminium-3S	Mild Steel
Rural	0.0025	0.025	5.8
Marine	0.0076	0.432	34.0
Marine Industrial	0.0076	0.686	46.2

Thermal Processing
1.    Annealing. Heat from 1010^oC to 1120^oC and cool rapidly in air or water. The best corrosion resistance is obtained when the final annealing is above 1070^oC and cooling is rapid.
2.    Stress relieving. 304L can be stress relieved at 450-600^oC for one hour with little danger of sensitisation. A lower stress relieving temperature of 400^oC maximum must be used.
3.     Hot working
        Initial forging and pressing:                              1150 to 1260^oC
        Finishing temperature:                                         900 to 925^oC
All hotworking operations should be followed by annealing.
Note: Soaking times to ensure uniformity of temperature are longer for stainless steels than for carbon steels - approximately 12 times.

Cold Working
304 / 304L being extremely tough and ductile, are readily fabricated by old working. Typical operations include bending, forming, deep drawing and upsetting