The three types of steel

Different types of steel are produced according to the mechanical and physical properties required for their application. Various grading systems are used to distinguish steels based on these properties, which include density, elasticity, melting point, thermal conductivity, strength, and hardness (among others). To make different steels, manufacturers vary the type and quantity of alloy metals, the production process, and the manner in which the steels are worked to produce particular products.

3 Types of Steel

According to the American Iron & Steel Institute (AISI), Steel can be categorized into four basic groups based on the chemical compositions:

1. Carbon Steel
2. Alloy Steel
3. Stainless Steel

There are many different grades of steel that encompass varied properties. These properties can be physical, chemical and environmental.

All steel is composed of iron and carbon. It is the amount of carbon, and the additional alloys that determine the properties of each grade.

Classifications
Types of Steel can also be classified by a variety of different factors:

1. Composition: Carbon range, Alloy, Stainless.
2. The production method: Continuous cast, Electric furnace, Etc.
3. Finishing method used: Cold Rolled, Hot Rolled, Cold Drawn (Cold Finished), Etc.
4. Form or shape: Bar, Rod, Tube, Pipe, Plate, Sheet, Structural, Etc.
5. De-oxidation process (oxygen removed from steelmaking process): Killed & Semi-Killed Steel, Etc.
6. Microstructure: Ferritic, Pearlitic, Martensitic, Etc.
7. Physical Strength (Per ASTM Standards).
8. Heat Treatment: Annealed, Quenched & Tempered, Etc.
9. Quality Nomenclature: Commercial Quality, Drawing Quality, Pressure Vessel Quality, Etc.

Steel Numbering Systems
There are two major numbering systems used by the steel industry, the first developed by the American Iron & Steel Institute (AISI), and the second by the Society of Automotive Engineers (SAE). Both of these systems are based on four digit code numbers when identifying the base carbon and alloy steels. There are selections of alloys that have five digit codes instead.

If the first digit is a one (1) in this designation it indicates a carbon steel. All carbon steels are in this group (1xxx) in both the SAE & AISI system. They are also subdivided into four categories due to particular underlying properties among them. See below:

• Plain Carbon Steel is encompassed within the 10xx series (containing 1.00% Mn maximum)
• Re-Sulfurized Carbon steel is encompassed within the 11xx series
• Re -Sulfurized and Re-Phosphorized Carbon Steel is encompassed within the 12xx series
• Non-Re-Sulfurized High-Manganese (up-to 1.65%) carbon steel is encompassed within the 15xx series.

The first digit on all other alloy steels (under the SAE-AISI system), are then classified as follows:

2 = Nickel steels.
3 = Nickel-chromium steels.
4 = Molybdenum steels.
5 = Chromium steels.
6 = Chromium-vanadium steels.
7 = Tungsten-chromium steels.
8 = Nickel-chromium-molybdenum steels
9 = Silicon-manganese steels and various other SAE grades

The second digit of the series (sometimes but not always) indicates the concentration of the major element in percentiles (1 equals 1%).
The last two digits of the series indicate the carbon concentration to 0.01%.
For example: SAE 5130 is a chromium alloy steel containing about 1% of chromium and approximately 0.30% of carbon.

Carbon Steel

Carbon Steel can be segregated into three main categories: Low carbon steel (sometimes known as mild steel); Medium carbon steel; and High carbon steel.

Low Carbon Steel (Mild Steel): Typically contain 0.04% to 0.30% carbon content. This is one of the largest groups of Carbon Steel. It covers a great diversity of shapes; from Flat Sheet to Structural Beam. Depending on the desired properties needed, other elements are added or increased. For example: Drawing Quality (DQ) – The carbon level is kept low and Aluminum is added, and for Structural Steel the carbon level is higher and the manganese content is increased.

Medium Carbon Steel: Typically has a carbon range of 0.31% to 0.60%, and a manganese content ranging from .060% to 1.65%. This product is stronger than low carbon steel, and it is more difficult to form, weld and cut. Medium carbon steels are quite often hardened and tempered using heat treatment.

High Carbon Steel: Commonly known as “carbon tool steel” it typically has a carbon range between 0.61% and 1.50%. High carbon steel is very difficult to cut, bend and weld. Once heat treated it becomes extremely hard and brittle.

Alloy Steels

Alloy steels are so named because they are made with a small percentage of one or more metals besides iron. The addition of alloys changes the properties of steels. For example, steel made from iron, chromium, and nickel produces stainless steel. The addition of aluminum can make steel more uniform in appearance. Steel with added manganese becomes exceptionally hard and strong.

Alloy steel is a steel that has had small amounts of one or more alloying elements (other than carbon) such as such as manganese, silicon, nickel, titanium, copper, chromium and aluminum added. This produces specific properties that are not found in regular carbon steel. Alloy steels are workhorses of industry because of their economical cost, wide availability, ease of processing, and good mechanical properties. Alloy steels are generally more responsive to heat and mechanical treatments than carbon steels.

The heat-treated type is available in both Annealed and Normalized. To learn more about Annealing and Normalizing, visit our Metal Glossary

Alloy Steel can be purchased online and at any Metal Supermarkets location. It can be cut to your exact specifications.

A333 PIPE SPECIFICATIONS

ASTM A333 covers nominal (average) wall seamless and welded carbon and alloy steel pipe intended for use at low temperatures. Several grades of ferritic steel are included. Some product sizes may not be available under this specification because heavier wall thicknesses have an adverse affect on low-temperature impact properties.

Chrome Moly Pipe

Chrome Moly Pipe has become a standard in the power generation industry and the petrochemical industry, not only because of its tensile strength, corrosion resistance and high-temperature strength, but also because of its cost-effectiveness. Grades P-11, P-22 – P-91 & P-92 are prevalent grades for the power industry, while P-5 & P-9 are the grades utilized in major refinery processing.

Common applications include food handling/processing, medical instruments, hardware, appliances, and structural/architectural uses.

Available standard and specification as below:

ASTM / ASME

American Society for Testing and Materials(ASTM), American Society of Mechanical Engineers (ASME)

Product name	Executive standard	Dimension (mm)	Steel code/ Steel grade
Seamless Ferritic and Austentic Alloy Steel Boiler, Superheater and Heat-Exchanger Tubes	ASTM A213	10.3~426 x 1.0~36	T5, T9, T11, T12, T22, T91
Wwall seamless and welded carbon and alloy steel pipe intended for use at low temperatures	ASTM A333	1/4″~42″ x SCH20~XXS	Gr1, Gr3, Gr6
Seamless Ferritic Alloy Steel Pipe for High-Temperature Service	ASTM A335	1/4″~4″ x SCH20~SCH80	P5, P9, P11, P12, P22, P91, P92
Seamless Carbon and Alloy Steel for Mechanical Tubing	ASTM A519	16″~42″ x 10~100mm	4130, 4130X, 4140

EN

Product name	Executive standard	Dimension (mm)	Steel code/ Steel grade
Seamless Ferritic Alloy Steel Pipes for High Temperature Use	EN 10216-2	8″~42″ x 15~100mm	13CrMo4-5, 1-CrMo9-10, X10CrMoVNb9-1, 15NiCuMoNb5-6-4

In Length of : Standard length, Double length & In Cut length also.
Other Services : Draw & Expansion as per required Size & Length, Heat Treatment, Bending, Anneling, Machining Etc.
Specialize : Heat Exchanger & Condenser Tubes

The Advantages Of Alloy Steel Pipe

The alloy steel pipe adopts high quality carbon steel, alloy structural steel and stainless & heat resisting steel as raw material through hot rolling or cold drawn to be made.

The main applications of alloy steel pipe is power station, nuclear power plant, high pressure boiler, high temperature superheater and re-heater coil etc. of high temperature pipeline and equipments.

The advantages of alloy steel pipe: 100% recycled, it is suitable for the national strategy of environmental protection, energy-saving and resource-saving. Therefore, the national policy encourages the expansion of the high pressure alloy steel pipe applications.

At present, the proportion of the total alloy steel tube is half of the developed countries. The applications of alloy steel pipe provide a broad space for the industry development. According to the research of the China association of special steel alloy pipe expert group, our country’s high pressure alloy steel pipe material demand grows by an average of up to 10-12%.

Stainless Steels

Stainless steel is a steel alloy with increased corrosion resistance compared to carbon/alloy steel. Common alloying ingredients include chromium (usually at least 11%), nickel, or molybdenum. Alloy content often is on the order of 15-30%.

• Austenitic steels, which are very high in chromium, also contain small amounts of nickel and carbon. These are very commonly used for food processing and piping. They are valued, in part, because they are non-magnetic.
• Ferritic steels contain about 15% chromium but only trace amounts of carbon and metal alloys such as molybdenum, aluminum, or titanium. These steels are magnetic, very hard and strong, and can be strengthened further by cold working.
• Martensitic steels contain moderate amounts of chromium, nickel, and carbon, They are magnetic and heat-treatable. Martensitic steels are often used for cutting tools such as knives and surgical equipment.

Stainless steel pipe Available Grades

Additionally, many austenitic stainless steels are weldable and formable. Two of the more commonly used grades of austenitic stainless steel are grades 304 and 316. To help you determine which grade is right for your project, this blog will examine the difference between 304 and 316 stainless steel.

Stainless Steel 304/304L
Excellent mechanical properties, resistance to many corrosive agents. Useful where sanitation and cleanliness are important. Non magnetic in the annealed condition. Hardness and tensile strength can be increased by cold working, but modified by lowered carbon content providing good resistance to corrosion in welded construction where subsequent heat treatment is not practical. Grade 304L (L= low carbon) is the same as the above except it has an extra-low-carbon analysis, the advantage of which is that it precludes any harmful precipitation in the 800º F to 1500º F range, such as might otherwise occur in welding heavier sections.
Typical Applications: Dairy, beverage and food product handling/processing equipment. Used for handling acetic, nitric, and citric acids; organic and inorganic chemicals, dye stuff, crude and refined oils; instruments; hospital equipment; applications requiring welding.
Available products: Round Bar, Rectangular Bar, Square Bar, Hexagonal Bar, Channel, Beam, Angle, Flat Sheet, Expanded Mesh,Perforated Sheet, Plate, Floor Plate, Pipe, Round Tube, Square Tube and Rectangular Tube
Typical Chemical Analysis: * C – .08 Max. *Mn – 2.00 Max. *P – .04 Max. *S – .03 Max. *Si – 1.0 Max. *Cr – 18.00/20.00 *Ni – 8.00/10.50 *Cu – .75 Max. *Mo – .75 Max.

Stainless Steel 316/316L
Pump shafts and parts in machinery used to process paper, textiles, chemicals and pharmaceuticals. In aircraft applications, used for parts requiring low magnetic permeability and good corrosion resistance.
Grade 316 is a standard molybdenum-bearing grade, the second most commonly sought after grade next to grade 304 amongst the austenitic stainless steels. The molybdenum gives 316 better overall corrosion resistant properties than Grade 304, particularly higher resistance in chloride environments. Grade 316L (L= low carbon) ) is the same as the above except it has an extra-low-carbon analysis, the advantage of which is that it precludes any harmful precipitation in the 800º F to 1500º F range that might result from welding heavier sections. Therefore 316L is extensively used in heavy gauge welded components. Typically there is no price difference between 316 and 316L stainless steel.

Typical Chemical Analysis:

1. * C – .08 Max. *Mn – 2.00 Max. *P – .04 Max. *S – .03 Max. *Si – 1.0 Max.
2. *Cr – 16.00/18.00 *Ni – 10.00 – 14.00 *Cu – .75 Max. *Mo – 2.00/3.00 Max. *N – .10 Max.

Typical Mechanical Properties**:

Data	Cold Finish (under 1⁄2” dia)	Cold Finish (over 1⁄2” dia)	Hot Rolled
Tensile Strength (PSI)	90-125,000	75,000 Min.	75-115,000
Yield Point (PSI)	45,000 Min.	30,000 Min.	30,000 Min.
Elongation	35 Min.	35 Min.	40 Min.

Chemical Analysis will vary on each heat number
All values are minimum values and are representative.

Types of Stainless Steel

The three main types of stainless steels are austenitic, ferritic, and martensitic. These three types of steels are identified by their microstructure or predominant crystal phase.

• Austenitic: Austenitic steels have austenite as their primary phase (face-centered cubic crystal). These are alloys containing chromium and nickel (sometimes manganese and nitrogen), structured around the Type 302 composition of iron, 18% chromium, and 8% nickel. Austenitic steels are not hardenable by heat treatment. The most familiar stainless steel is probably Type 304, sometimes called T304 or simply 304. Type 304 surgical stainless steel is an austenitic steel containing 18-20% chromium and 8-10% nickel.
• Ferritic: Ferritic steels have ferrite (body centered cubic crystal) as their main phase. These steels contain iron and chromium, based on the Type 430 composition of 17% chromium. Ferritic steel is less ductile than austenitic steel and is not hardenable by heat treatment.
• Martensitic: The characteristic orthorhombic martensite microstructure was first observed by German microscopist Adolf Martens around 1890. Martensitic steels are low carbon steels built around the Type 410 composition of iron, 12% chromium, and 0.12% carbon. They may be tempered and hardened. Martensite gives steel great hardness, but it also reduces its toughness and makes it brittle, so few steels are fully hardened.

There are also other grades of stainless steels, such as precipitation-hardened, duplex, and cast stainless steels. Stainless steel can be produced in a variety of finishes and textures and can be tinted over a broad spectrum of colors.

Chrome Moly Tubing

Chrome Moly Tubing is High Quality Mechanical Steel tubing, which is in Form of Cold Drawn. Crome-Moly Tubing is manufactured under MIL-T- 6736 B (AMS-T-6736A), AMS-6371 and AMS-6360 standards. These tubing are heat treatable, though Hardenable easily machined. Tensile strength after heat treatment 860 N/mm2. Welded areas require heat treatment after welding to retain strength. Chrome Moly tubing are also known as Alloy tubing. General Abbreviations of chrome moly tubing are chrome-moly, cro-moly, CrMo, CRMO, CR-MOLY ASTM A213 are often called as chrome moly tubing because of the chemical contain of Molybdenum (Mo) and Chromium (Cr). Molybdenum increases the strength of steel and Chromium (or chrome) is the essential constituent of stainless steel. The composition chrome moly alloy steel Tubing make it ideal for use in power plants, refineries, petro chemical plants, and oil field services where fluids and gases are transported at extremely high temperatures and pressures.

Advantages:

• Consistent Workability
• Preferred Fabrication
• Higher than Standard Mechanical Properties
• Indian Drawn 4130 steel tubing

Applications
Chrome moly pipe under ASTM & ASME specification A/SA 213 T1, T2, T11, T12, T15, T22, T91, T92, T122 are used for power industries whereas ASTM/ASME A/SA 213 T5, T9 are used for petrochemical industries

Certification
Chrome Moly tubing are certified as PER DIN 50049 3.1, EN 10204 3.1/3.2 and NACE MR-0175 & NACE MR-0103

Size
½- – 3- Outer Diameter Thickness- 1mm-12mm. Chrome Moly tubing are supplied in single random length and double random length of 4-7 meters and 7-13 meters respectively.

Piping Component Specifications

• Flanges and forged fittings – A/SA 182 F1, F2, F5, F9, F11, F12, F15, F22, F91, F92, F122
• Wrought Butt-weld Pipe Fittings – A/SA 234 P1, P2, P5, P9, P11, P12, P15, P22, P91, P92, P122

ASME

ASME SA 213 Grade T1 Tubing
ASME SA 213 Grade T2 Tubing
ASME SA 213 Grade T5 Tubing
ASME SA 213 Grade T5b Tubing
ASME SA 213 Grade T5c Tubing
ASME SA 213 Grade T9 Tubing

ASME SA 213 Grade T11 Tubing
ASME SA 213 Grade T12 Tubing
ASME SA 213 Grade T15 Tubing
ASME SA 213 Grade T21 Tubing
ASME SA 213 Grade T22 Tubing
ASME SA 213 Grade T23 Tubing

ASME SA 213 Grade T24 Tubing
ASME SA 213 Grade T36 Tubing
ASME SA 213 Grade T91 Tubing
ASME SA 213 Grade T92 Tubing
ASME SA 213 Grade T122 Tubing
ASME SA 213 Grade T911 Tubing

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ASTM

ASTM A213 Grade T1 Tubing
ASTM A213 Grade T2 Tubing
ASTM A213 Grade T5 Tubing
ASTM A213 Grade T5b Tubing
ASTM A213 Grade T5c Tubing
ASTM A213 Grade T9 Tubing

ASTM A213 Grade T11 Tubing
ASTM A213 Grade T12 Tubing
ASTM A213 Grade T15 Tubing
ASTM A213 Grade T21 Tubing
ASTM A213 Grade T22 Tubing
ASTM A213 Grade T23 Tubing

ASTM A213 Grade T24 Tubing
ASTM A213 Grade T36 Tubing
ASTM A213 Grade T91 Tubing
ASTM A213 Grade T92 Tubing
ASTM A213 Grade T122 Tubing
ASTM A213 Grade T911 Tubing

SA213 Heater Tubes

Sunny Steel is a premier worldwide supplier for all your Chrome Moly Alloy A213 / SA213 Heater Tubes needs.

ASTM A213 Standard Specification for Seamless Ferritic and Austenitic Alloy-Steel Boiler, Superheater, and Heat-Exchanger Tubes

ASTM A213M-09 standard is issued under the fixed designation A 213/A 213M; the number immediately following the designation indicates the year of original adoption or, in the case of revision, the year of last revision.

ASME/ ASTM SA213/ A213 standard is issued under the fixed designation A 213/A 213M; the number immediately following the designation indicates the year of original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A superscript epsilon (′) indicates an editorial change since the last revision or reapproval.

Thisstandardhas been approved for use by agencies of the Department of Defense.

Scope

1.1 This specication2 covers seamless ferritic and austenitic steel boiler,superheater, andheat-exchanger tubes, designated Grades T5,TP304, etc. These steels are listed in Tables 1 and 2.

1.2 Grades containing the letter, H, in their designation, have requirements different from those of similar grades not containing the letter, H. These different requirements provide higher creep-rupture strength than normally achievable in similar grades without these different requirements.

1.3 The tubing sizes and thicknesses usually furnished to this specication are 18 in. [3.2 mm] in inside diameter to 5 in. [127 mm] in outside diameter and 0.015 to 0.500 in. [0.4 to 12.7 mm], inclusive, in minimum wall thickness or, if specied in the order, average wall thickness. Tubing having other diameters may be furnished, provided such tubes comply with all other requirements of this specication.

1. The values stated in either SI units or inch-pound units are to be regarded separately as standard. Within the text, the SI units are shown in brackets. The values stated in each system may not be exact equivalents; therefore, each system shall be used independently of the other. Combining values from the two systems may result in non-conformance with the standard. The inch-pound units shall apply unless the “M” designation of this specication is specied in the order.

Ordering Information

Orders for material under this specification should include the following, as required, to describe the desired material adequately:

Quantity	Feet, meters, or number of lengths
Name of material	Seamless Alloy Steel Pipe
Grade	STANDARD AND STEEL GRADE
Manufacture	Hot-finished or cold-drawn
Size using one of the following:
NPS and Schedule Number
Outside Diameter and Nominal Wall Thickness
Length	Specific or Random
End Finish

Size (mm) we can supply:

Hot-rolled: O.D.: 51-508; W.T.:7∼60; L: max 16000

Cold-drawn: O.D.: 10-50; W.T.:2∼10; L: max 16000

Hot-expanded：O.D.: 325-1020; W.T.:6∼50; L: max 12000 and other specifications in accordance with customer requirements.

Packing:

Beveled/black painting/ plastic caps/ in bundles/ steel strips/ wooden protection

Inspection and Test:

Chemical Composition Inspection, Mechanical Properties Test(Tensile Strength, Yield Strength,Elongation, Flaring, Flattening, Bending, Hardness, Impact Test), Surface and Dimension Test, Nodestructive Test, Hydrostatic Test.

Surface Treatment:

Oil-dip, Varnish, Passivation, Phosphating, Shot Blasting, Epoxy & Fbe Coating Painting as requested.

Referenced Documents

2.1 ASTM Standards:3

1 This specication is under the jurisdiction of ASTM Committee A01on Steel,Stainless Steeland Related Alloys and is the direct responsibility of Subcommittee A01.10 on Stainless and Alloy Steel Tubular Products.

Current edition approved April 1, 2009. Published April 2009. Originally approved in 1939. Last previous edition approved in 2009 as A 213/A 213M – 09.

2 For ASME Boiler and Pressure Vessel Code applications see related Specication SA-213 in Section II of that Code.

3 For referenced ASTM standards, visit the ASTM website, www.astm.org, or contact ASTM Customer Service at service@astm.org. ForAnnualBookofASTM Standards volume information, refer to the standard’s Document Summary page on the ASTM website.

A 262 Practices for Detecting Susceptibility to Intergranu lar Attack in AusteniticStainless Steels

A 941 Terminology Relating to Steel,Stainless Steel, Re lated Alloys, and Ferroalloys

A 1016/A 1016M Specication for General Requirements for Ferritic AlloySteel, Austenitic Alloy Steel, andStainless Steel Tubes

E112 Test Methods for Determining Average Grain Size

3. Terminology

1. Denitions—For denitions of terms used in this specication, refer to Terminology A 941.

2. Ordering Information

4.1 It shall be the responsibility of the purchaser to specify all requirements that are necessary for products under this specication. Such requirements to be considered include, but are not limited to, the following:

4.1.1 Quantity (feet, metres, or number of lengths),

4.1.2 Name of material (seamless tubes),

4.1.3 Grade (Tables 1 and 2),

4.1.4 Condition (hot nished or cold nished),

4.1.5 Controlled structural characteristics (see 6.3),

4.1.6 Size (outside diameter and minimum wall thickness, unless average wall thickness is specied),

4.1.7 Length (specic or random),

4.1.8 Hydrostatic Test or Nondestructive Electric Test (see 10.1),

4.1.9 Specication designation and year of issue,

4.1.10 Increased sulfur (for machinability, see Note B, Table 1, and 15.3), and

Special requirements and any supplementary requirements selected.

General Requirements

5.1 Product furnished to this specication shall conform to the requirements of SpecicationA 1016/A 1016M, including any supplementary requirements that are indicated.

Nominal Pipe Size(NPS): 1/8, 1/4, 3/8, 1/2, 3/4, 1, 1 1/4, 1 1/2, 2, 2 1/2 inch

Outside Diameter: 10,3 – 73 mm (0,405 – 2,875 inch)

Wall Thickness: 1,24 – 7,01 (0,049 – 0,276 inch)

Review of Procurement Requirements:

It shall be the responsibility of the purchaser to specify all necessary requirements. Such requirements to be considered include, but are not limited to, the following:

• Quantity (feet, metres, or number of lengths)
• Name of material (seamless tubes)
• Grade
• Condition (hot finished or cold finished)
• Controlled structural characteristics
• Size (outside diameter and minimum wall thickness, unless average wall thickness is specified)
• Length (specific or random)
• Hydrostatic Test or Nondestructive Electric Test
• Increased sulfur (for machinability)
• Specification designation and year of issue
• Special requirements and any supplementary requirements selected

Notes:

Steel Grades -TP 304, TP 304L, TP 316, TP 316L, TP 321, T5, T11, T12, T13, T91

Technical requirements acc. to ASTM A 450.

Size of pipes in accordance with ANSI/ASME B36.19M.

The quality of pipes is ensured by manufacturing process and non-destructive test.

Hardness of metal not less than 100 HB.

Length tolerance of measured pipes not greater than +10 mm.

Monitoring of continuity of metal by pneumotest with pressure of 6 bar is available.

Intergranular corrosion test in accordance with ASTM A262, Practice E is available.

Weight Count:(just for Alloy Steel)

Weight(Kg/M)=(OD-WT)*WT*0.02466 , OD:Outside Diameter, WT:Wall-Thickness

Heat exchanger tube

A shell and tube heat exchange is a class of heat exchange designs. It is the most common type of heat exchange in oil refineries and other large chemical processes, and is suited for higher-pressure applications.

Heat exchange tubes are intended for heating or cooling process fluids, they are for example suitable for closed circuit cooling of electrical equipment using demineralised water and for cooling water soluble oil solutions in quenching tanks.

Sunny Steel supply a 1/2 million foot inventory of carbon steel pressure tubing including boiler tubes, condenser tubes and heat exchanger tubes all made in the China.

Production Standard, Steel Grade:

It is manufactured from quality stainless steel, which is suitable of all types of heat exchangers, such as seawater coolers, condensers, evaporators, heaters and re-heaters. We provide these in several sizes, lengths and dimensions as per the requirement of our clients. The Heat exchange tubes can withstand enormous pressure and high temperatures from the hot combustion gases of the fireboxes.
Features:

• Cost effective
• Rugged construction
• High tensile
• Supreme impact strength

Technical Specifications:

EQ-STANDARDS INDUSTRY	INDIAN IS	BRITISH BS	JAPANESE JIS	GERMAN DIN	AMERICAN ASTM/API	EUROPION STANDARD
Heat Exchanger Tubes	IS 3074/1979	BS 3606/1982	JISG 3461/1984	DIN 17177/1979	ASTM A178/1990 ASTMA214/1990	BS EN 10305-2 BS EN 10305-3

Our carbon steel pressure tubing inventory is manufactured in accordance with ASME SA-178 A and/or ASME SA-214 in diameters of 3/4″ through 4”.

Available grades:

• 304, 304H, 304L, 321, 321H, 316, 316L, 316H, 317, 317L, 317LMN, 316Ti
• 347, 347H, 310S, S31803/S32205, S32750/S32507, S32760
• 1.4301, 1.4306, 1.4401, 1.4404, 1.4541, 1.4845, 1.4438

Specification:

• ASTM A179
• ASTM A213
• ASME SA213
• ASTM A789
• ASTM A790
• DIN17456
• DIN17458
• EN10216-5

Dimensions:

• OD: 12.7/15.88/19.05/25.4/31.8/38.1/50.8mm
• WT: 0.89/1.24/1.65/2.11/2.77/3.05/3.4mm
• Length: 25 meters maximum

Surface condition: bright annealed and pickled
Delivery Conditions:Annealed, Normalized, Normalized and Tempered

Inspection and Test:
Chemical Composition Inspection, Mechanical Properties Test(Tensile Strength,Yield Strength, Elongation, Flaring, Flattening, Hardness, Impact Test), Surface and Dimension Test,No-destructive Test, Hydrostatic Test.
Surface treatment:Oil-dip, Varnish, Passivation, Phosphating, Shot Blasting.

Application:For tubular heat exchangers, condensers and similar heat transfer apparatus.

Here are a few of the most common types of heat exchangers that you will hear about:

The possible flexibility in design of these exchangers is mainly responsible for their wide use in a range of applications. These exchangers do not have design limitations in terms of temperature and pressure. These exchangers are easy to maintain. These exchangers can be easily designed to accommodate thermal stresses.

A shell and tube heat exchanger is a class of heat exchanger designs. It is the most common type of heat exchanger in oil refineries and other large chemical processes, and is suited for higher-pressure applications.

1. Shell and Tube Heat Exchanger:
   In a shell and tube heat exchanger, two fluids at different temperatures flow through tubes. One set of tubes is outside, and one is in the shell of the unit. Heat is transferred through the tube walls. The fluid in the tubes can be in liquid or gas form. A one phase unit is used for only heating or cooling, while a two phase can be used for both.
2. Air to Air Heat Exchanger:
   These exchangers work to heat, cool or refresh the air in a space.
3. Water to Water Heat Exchanger:
   A water to water heat exchanger continually cycles hot or cold water through tubes to heat or cool it again before sending it in the other direction.
4. Air to Water Heat Exchanger:
   Water runs through tubes that are cooled or heated by a stream of air running over them.
5. Gas to air heat exchanger:
   In a gas to air heat exchanger, heat created by gas flows upwards and is then pushed out of the exchanger’s exhaust.

This list is by no means exhaustive, but these five types of heat exchangers can be found in many buildings and commercial facilities. We’ll help you find the replacement parts and heat exchanging units that you’re looking for, whether they’re for units like the ones on this list or not.

Seamless pipes for high temperature and pressure service

Sunny Steel offer an extensive range of Seamless steel pipes for high temperature and pressure service.

ASTM A335 P12 high pressure semaless boiler pipe, The range of ASTM A335 P12 seamless alloy steel pipe sizes that may be examined by each method shall be subjected to the limitations in the scope of the respective practice.

High Pressure and Temperature Service Seamless Pipes are application for heating-pipelines, containers, coal-saving devices superheaters and reheaters of high temperature and high press boiler by the main standard GB5310-2008, GB9948-2006, GB6479-2000, ASTM/ASME A/SA213, ASTM/ASME A/SA335, EN10216-2, ASTM/ASME A/SA312.

Application:
heating-pipelines, containers, coal-saving devices superheaters and reheaters of high temperature and high press boiler(P>=9.8MPa, T>450oC)

Pipe Grades:
GB5310-2008, GB9948-2006, GB6479-2000
ASTM/ASME A/SA213 Gr. T2, T5, T5b, T5c, T11, T12, T17, T21, T22, T9, T91
ASTM/ASME A/SA335 Gr. P1, P2, P5, P11, P12, P22
ASTM/ASME A/SA312 Gr. TP304H, TP347H, TP310S/310H
TP316L, TP321H, TP317L, TP410/410S, TP420
EN10216-2 Gr. 10CrMo9-10,13CrMo4-5,EN10216-2,P195GH,P235GH,P265GH

Available Sizes:
O.D.: from 3/4 to 20 inch
W.T.: 0.102 to 4inch (2.6 to 100 mm)
Length: max 16000mm

Marking:
Pipes are supplied with marking according to standard and customer request.
Marking is paint on the ends of pipes.
The same data, as well as additional information per customer’s request, is indicated on the bundle’s tags.
Delivery:
Pipes are supplied in hexagonal bundles or round bundles tied with steel strip.
Weight of bundle – up to 5000 kg upon request of customer.
Each bundle is furnished with three tags.

Heat exchanger tube

Heat exchange tubes are intended for heating or cooling process fluids, they are for example suitable for closed circuit cooling of electrical equipment using demineralised water and for cooling water soluble oil solutions in quenching tanks.

Sunny Steel supply a 1/2 million foot inventory of carbon steel pressure tubing including boiler tubes, condenser tubes and heat exchanger tubes all made in the China.
Our carbon steel pressure tubing inventory is manufactured in accordance with ASME SA-178 A and/or ASME SA-214 in diameters of 3/4″ through 4”.

Production Standard, Steel Grade:

Available grades:

304, 304H, 304L, 321, 321H, 316, 316L, 316H, 317, 317L, 317LMN, 316Ti
347, 347H, 310S, S31803/S32205, S32750/S32507, S32760
1.4301, 1.4306, 1.4401, 1.4404, 1.4541, 1.4845, 1.4438
Specification:

ASTM A179, ASTM A213, ASME SA213, ASTM A789, ASTM A790
DIN17456, DIN17458 and EN10216-5
Dimensions:

OD: 12.7/15.88/19.05/25.4/31.8/38.1/50.8mm
WT: 0.89/1.24/1.65/2.11/2.77/3.05/3.4mm
Length: 25 meters maximum
Surface condition: bright annealed and pickled
Delivery Conditions:Annealed, Normalized, Normalized and Tempered
Inspection and Test:
Chemical Composition Inspection, Mechanical Properties Test(Tensile Strength,Yield Strength, Elongation, Flaring, Flattening, Hardness, Impact Test), Surface and Dimension Test,No-destructive Test, Hydrostatic Test.
Surface treatment:Oil-dip, Varnish, Passivation, Phosphating, Shot Blasting.

Application:For tubular heat exchangers,condensers and similar heat transfer apparatus.