254 SMO stainless steel tube

254 SMO stainless steel tube is an austenitic stainless steel tube. Due to its high molybdenum content, it has extremely high pitting and crevice corrosion resistance.

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Category: Stainless pipe

Description

254 SMO stainless steel tube is an austenitic stainless steel tube. Due to its high molybdenum content, it has extremely high pitting and crevice corrosion resistance.

254 SMO is a high-performance austenitic stainless steel that contains high levels of chromium, molybdenum, and nitrogen. It is also known as UNS S31254 or 6 Moly due to its composition. 254 SMO stainless steel tubes are tubes made from this material and are suitable for use in corrosive environments.

This material has excellent resistance to pitting, crevice corrosion, and stress corrosion cracking, making it ideal for use in seawater handling equipment, chemical process vessels, and oil and gas production equipment.

Some of the key features of 254 SMO stainless steel tubes include:

Excellent corrosion resistance: 254 SMO has superior resistance to corrosion in a wide range of aggressive environments, including seawater, acidic chloride-containing media, and other harsh chemical environments.
High strength: 254 SMO stainless steel tubes have high strength and are capable of withstanding high pressure and temperature conditions.
Good weldability: 254 SMO can be welded using conventional welding techniques such as TIG, MIG, and SMAW.
Low thermal expansion: 254 SMO has a low coefficient of thermal expansion, which means that it is less likely to distort or deform under high-temperature conditions.

254 SMO stainless steel tubes are widely used in offshore and onshore applications involving harsh environments, as well as in the chemical and petrochemical industries, desalination plants, and pulp and paper manufacturing.

Manufacturing process

Since the 254S MO stainless steel tube is a high-alloy material, it is quite complicated in the manufacturing process. Generally, people can only rely on traditional techniques to manufacture such special stainless steel tubes, such asseamless, pouring, forging, calendering and the like.

Heat treatment

If additional heat treatment is needed due to further processing the following is recommended.
Solution annealing 1150–1200°C (2100–2190°F), quenching in water. Thin-walled tubes min. 1130°C (2060°F), quenching in air/water.

National standards

UNS S31254, DIN/EN 1.4547, ASTM A280, ASME SA-240

Matching welding consumables

ERNiCrMo-3 welding wire, ENiCrMo-3 welding rod

Chemical composition (nominal) %

Standards	Grade	C	Si	Mn	P	S	Cr	Ni	Mo	N	Cu
Outokumpu	254 SMO	≤0.020	≤0.80	≤1.00	≤0.030	≤0.010	19.5-20.5	17.5-18.5	6.0-6.5	0.18-0.22	0.5-1.0
ASTM A182	F44 S31254	≤0.020	≤0.80	≤1.00	≤0.030	≤0.010	19.5-20.5	17.5-18.5	6.0-6.5	0.18-0.22	0.5-1.0
DIN EN 10088-3-2005	X1CrNiMoN20-18-71.4547	≤0.020	≤0.70	≤1.00	≤0.030	≤0.010	19.5-20.5	17.5-18.5	6.0-7.0	0.18-0.25	0.5-1.0

Mechanical properties

Standards	Grade	Tensile strength	Yield strength	Elongation	Hardness
Outokumpu	254 SMO	≥650 MPa	≥300 MPa	≥ 35%	≤96 HRB

Features of 254SMO stainless steel tube

254SMO stainless steel pipes also have high crevice corrosion resistance in seawater, and only a few types of stainless steel pipes have this property.
The corrosion resistance of 254SMO stainless steel tubes in acidic solutions and oxidizing halide solutions such as paper bleaching can be compared to nickel-based alloys and titanium alloys with the strongest corrosion resistance.
Since the 254SMO stainless steel tube has a high nitrogen content, its mechanical strength is higher than other types of austenitic stainless steel tubes. In addition, the 254SMO stainless steel tube also has high ductility and impact strength as well as good weldability.
The high molybdenum content of the 254SMO stainless steel tube allows it to have a higher oxidation rate during annealing, resulting in a rougher surface than the normal stainless steel tube after pickling. However, this has no adverse effect on the corrosion resistance of the steel.

Application areas of 254SMO stainless steel pipe

Ocean: marine structures in the sea environment, seawater desalination, marine aquaculture, seawater heat exchange, etc.
Environmental protection field: flue gas desulfurization device for thermal power generation, wastewater treatment, etc.
Energy field: atomic power generation, comprehensive utilization of coal, and ocean wave power generation.
Petrochemical industry: refining, chemical and chemical equipment.
Food field: salt making, soy sauce brewing, etc.
High concentration chloride ion environment: paper industry, various bleaching devices

Standard & Grade

Normal standard

Item	ASTM A213/A213M		ASTM A312/A312M
Grade	TP304	TP304L	TP304	TP304L
	TP316	TP316L	TP316	TP316L
	TP317	TP317L	TP317	TP317L
	TP347	TP310S	TP347	TP310S
	TP309H*	TP310H*	TP317*	TP310H*
		TP321HΔ		TP321HΔ

Normal chemical composition of stainless steel

Grade	C (max)	Si (max)	Mn (max)	P (max)	S (max)	Ni	Cr
TP 304	0.08	0.75	2	0.04	0.03	8-11	18-20
TP 304H	0.04-0.10	0.75	2	0.04	0.03	8-11	18-20
TP 304L	0.035	0.75	2	0.04	0.03	8-13	18-20
TP 309S	0.08	0.75	2	0.04	0.03	8-13	18-20
TP 310S	0.08	0.75	2	0.045	0.03	12-15	22-24
TP 316	0.08	0.75	2	0.04	0.03	19-22	24-26
TP 316L	0.035	0.75	2	0.04	0.03	10-15	16-18
TP 316Ti	0.08	0.75	2	0.04	0.03	11-14	16-18
TP 317	0.08	0.75	2	0.04	0.03	11-14	16-18
TP 321	0.08	0.75	2	0.04	0.03	9-13	18-20
TP 321H	0.04-0.10	0.75	2	0.04	0.03	9-13	17-20
TP 347	0.08	0.75	2	0.04	0.03	9-13	17-20
TP 347H	0.04-0.10	0.75	2	0.04	0.03	9-13	17-20

Grade	Tensile Strength Min(Mpa)	Yeild Point Min(Mpa)	EL. Min(%)	Rockwell Max
TP 304	515	205	35	90
TP 304H	550	240	35	90
TP 304L	485	170	35	90
TP 309S	515	205	35	90
TP 310S	515	205	35	90
TP 316	515	205	35	90
TP 316L	485	170	35	90
TP 316Ti	515	205	35	90
TP 317	515	205	35	90
TP 321	515	205	35	90
TP 321H	515	205	35	90
TP 347	515	205	35	90
TP 347H	515	205	35	90

Heat treatment technology of stainless steel pipe surface

For the heat treatment technology of the surface of stainless steel pipes, non-oxidation continuous heat treatment furnaces with protective gas are generally used abroad for intermediate heat treatment and final heat treatment of finished products. As a bright surface without oxidation can be obtained, the traditional pickling process is eliminated. The adoption of this heat treatment process not only improves the surface of stainless steel pipes, but also overcomes the environmental pollution caused by pickling.

According to the manufacturer of stainless steel pipes, according to the current world development trend, bright annealing continuous heat treatment furnaces are basically divided into the following two types:

(1) Roller-type bright annealing heat treatment furnace.

This bright annealing furnace type is suitable for heat treatment of large-size and large-volume special-shaped stainless steel pipes, with an hourly output of above 1.0 Tons. The protective gases that can be used are high-purity hydrogen, decomposed ammonia and other protective gases. It can be equipped with a convection cooling system to cool the special-shaped stainless steel tube faster.

(2) Mesh belt type bright annealing heat treatment furnace.

This bright annealing furnace type is suitable for small-diameter thin-walled precision special-shaped stainless steel pipes. The hourly output is about 0.3 to 1.0 Tons. The length of the steel pipe can be up to 40m. It can also be used to process capillary tubes in coils. Equipped with convection cooling system for fast cooling. Using gas fuel or electric heating, various protective gases can be used. The stainless steel pipe after this furnace-type heat treatment has no scratches and good brightness surface.

Tensile test and hardness test of stainless steel pipe?

Tensile strength test is to make a sample of stainless steel pipe, pull the sample to break on a tensile testing machine, and then measure one or several mechanical properties, usually only the tensile strength, yield strength, elongation after fracture and section are measured Shrinkage. Tensile strength test is the most basic test method for mechanical properties of metal materials. Almost all metal materials require tensile test as long as they have requirements for mechanical properties. Especially for those materials whose shape is not convenient for hardness test, tensile strength test becomes the only means of testing mechanical properties.

The hardness test is to slowly press a hard indenter into the surface of the sample with a durometer under specified conditions, and then test the depth or size of the indentation to determine the hardness of the material. Hardness test is the simplest, fastest and easiest method in material mechanical property test. The hardness test is non-destructive, and there is an approximate conversion relationship between the material hardness value and the tensile strength value. The hardness value of the material can be converted into the tensile strength value, which has great practical significance.

Because the tensile strength test is not easy to test, and it is convenient to convert the hardness to the strength, more and more people only test the hardness of the material and less test its strength. In particular, due to the continuous advancement of hardness tester manufacturing technology and innovations, it is now possible to directly test the hardness of some materials that could not be directly tested before, such as stainless steel tube, stainless steel sheet and stainless steel strip. Therefore, there is a tendency for hardness tests to gradually replace tensile tests.

Process

Our specialized process for seamless tubing manufacturing begins with either an extruded hollow tube or a solid bar drilled to our exacting specifications. The material is then reduced in size a number of times through various cold working techniques until it reaches the specific size, tolerances, and temper required by our customer. After each cold working cycle the tubes are cut, cleaned and heat treated in preparation for the next cold working step.

Cold finished stainless steel tube technology flow chart

Pilfering

Pilfering reduces the size of the tube across three dimensions – outside diameter (OD), internal diameter (ID) and wall thickness. We roll a die set with a tapered groove across the outside of the tube while supporting the inside diameter using a taper-matched, hardened steel mandrel.

In a single cold working step, we can achieve a significant reduction in cross-sectional area while minimizing material loss and, most importantly, improving the material’s microstructure. Seamless tubes constitute the majority of volume processed by tube reducing or pilgering.

Cold Rolling

Like pilgering, tube rolling also uses compression to reduce the size of seamless tubes. However, while pilgering uses a pair of grooved, tapered dies to work the metal over a tapered mandrel, tube rolling utilizes one or two sets of rolls with constant cross-section grooves on the circumference of the tube.

Generally, the process employs a cylindrical mandrel with little or no taper. The rolls are driven by rack and pinion gears of different radii along profiled cams, completing multiple 360º rotations around the tube.

Cold rolling is a very precise method of reducing very thin walled and/or smaller diameter tubes, and is often used as the final cold working step. By rolling, we’re able to achieve exceptional control over dimensional tolerances and surface finish while also minimizing material loss and improving the metal’s microstructure.

Because it uses compression, tube rolling is well suited to processing unique metals like titanium and zirconium alloys.
Our cold rolling capabilities include both classic 2-roll (single roll set) tube rollers and an advanced 3-roll approach.

Cold Drawing

Typically used as the first form of size reduction for seamless tubes, cold drawing reduces the diameter by pulling the tube through a die that is smaller than the tube. In order to fit the tube into the die, one end is ‘swaged’ or ‘tagged’ thereby reducing the diameter of the leading end before drawing. Next, the narrowed end is passed through the die and clamped to a drawing trolley which pulls the tube through the die. After drawing the ‘tag’ is cropped from the tube end prior to cleaning.

Three types of cold drawing techniques:

Sink drawing

This is the simplest of the three drawing methods, as there is no tooling to support the ID surface. The tube is drawn through a die made of polished tool steel or industrial diamond, thereby reducing its inside and outside diameters. Our specialized lubrication and application techniques, combined with our proprietary die profiles, enable the OD surface to become smoother as the tube is drawn. Since the inside diameter is not constrained, the wall thickness of the tube will normally increase during drawing, and the ID surface finish will normally become rougher during a sink draw.

Rod drawing

Rod drawing is our most commonly used cold draw method, primarily for intermediate or in-process drawing stages, where both the outside diameter and wall thickness are reduced at the same time.

The tube is loaded over a hardened steel mandrel rod and both are then drawn through a die. This squeezes the tube onto the rod, reducing the outside diameter and thinning the wall simultaneously. The die and mandrel determine the size of the drawn tube, which is then slightly expanded by applying pressure to the outside of the tube so that the rod can be removed. Since larger reductions in cross-sectional area can be achieved by rod drawing, this method is used for mid-process stages to reduce tube sizes prior to the final drawing cycle.

Plug drawing

This type of drawing is used to achieve the best possible surface finish and the greatest control over both dimensions and final temper. The outside diameter and wall thickness of the tube are both reduced during plug drawing, as the tube travels through a die and over a stationary plug/mandrel made of high grade tool steel. The plug or mandrel has a polished surface and is attached to a fixed back rod, which is carefully positioned within the drawing die. The tube is loaded over the mandrel/back rod. As the tube passes through the die, the burnishing action of the metal flowing over the stationary plug imparts a high tolerance surface finish inside the tube.

When properly lubricated and prepared, the ID will show very few flaws and finishes of 16 RMS or better can be achieved. Plug drawing is normally chosen for the final draw stage because it achieves a high quality surface finish, exceptional dimensional control, and positive influence on tensile strength requirements.

Annealing

Annealing is used to soften the metal before further cold working or fabrication processes, and improves the overall metallurgical microstructure of the tube. During tube reduction or cold drawing, it can become hard and somewhat brittle. To be able to draw the tube again, stresses formed during cold working need to be removed to return the material to its normal state.

During annealing the tube is heated to a controlled temperature (up to 2100°F) and soak time. Through this process the tube remains in shape, but the grains in the structure of the tube reform into a regular unstressed pattern. The resulting annealed tube is softer and suitable for redrawing.

Our closely controlled annealing and heat treat processes are audited regularly by our nuclear, medical, and aerospace customers.

Straightening

Drawing and annealing generally results in some degree of bowing, producing a slight bend in the tubing. We use multiple roll mechanical straighteners in the first stage of finishing. The straightener applies pressure and flex to the product in order to remove bends or bows, resulting in a straightness level of 0.010” per foot, or better. Straightening can introduce slight changes to the size and mechanical properties of the tubing, so these aspects are very carefully controlled during the process.

Marking: SunnySteel, material grade, standard, specification, heat no.
Surface Treatment: Bright annealed, polished outside and inside surface.
Package: knitting strip bundle, wooden box or steel box
Mill test certificate: according to EN 10204 3.2
Inspection: Third party inspection, or by clints

Packing

There are probably hundreds of different methods for packing stainless pipe, and most of them have merit, but there are two principles that are vital for any method to work prevent rusting and Sea transportation security.

We inventory stainless steel grades that are readily used in manufacturing such as 304, 304L and 316/L to harder to find items such as 309H, 330 or 405 stainless.

the wooden boxes packing for stainless products

Application

Stainless steel pipe (tube) has excellent characteristics of corrosion resistance and smooth finishing. Stainless steel pipe (tube) is commonly used in demanding equipment like automobiles, food processing, water treatment facilities, oil and gas processing, refinery and petrochemicals, breweries and energy industries.

Stainless steel tube is typically measured by its outer diameter and can be used in a variety of applications including a number of structural applications. Stainless steel tubing is extremely durable and able to withstand corrosion. This tubing will not rust, even if exposed to the elements, heat, and other extreme conditions. Because of these factors, stainless steel tubing can be used for a wide variety of applications.

The stainless steel tubing that is supplied by SunnySteel can used in a variety of industries, including:

Considering the importance of outside and inside surface of stainless steel tubes for fluid power industry, Our mills are providing tubes that are free from scale, rust, seams, laps.

Machinery Parts
Food and Beverage Processing
Pharmaceutical
Biotechnology
Automotive

Marine
Construction
Chemical
Oil and Gas

the main requirement for stainless steels is that they should be corrosion resistant for a specified application or environment. The selection of a particular “type” and “grade” of stainless steel must initially meet the corrosion resistance requirements.

Additional mechanical or physical properties may also need to be considered to achieve the overall service performance requirements.

Inquiry

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FAQ

Q: How long is your delivery time?
A: The delivery time of customized products is generally 25 35 days, and non customized products are generally shipped within 24 hours after payment.

Q: Do you provide samples? Is it free?
A: If the value of the sample is low, we will provide it for free, but the freight needs to be paid by the customer. But for some high value samples, we need to charge a fee.

Q: What are your payment terms?
A: T/T 30% as the deposit,The balance payment is paid in full before shipment

Q: What is the packaging and transportation form?
A: Non steaming wooden box and iron frame packaging. Special packaging is available according to customer needs. The transportation is mainly by sea.

Q: What is your minimum order quantity?
A: There is no minimum order quantity requirement. Customized products are tailor made according to the drawings provided by the customer.