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Our team is highly trained and experienced in servicing and producing all types of steel supplies. Need help or have a question?
sales@abrasionresistantpipe.com
Tel.: +8621-3378-0199
ASTM A178 Boiler and Superheater Tubes for Electric-Resistance-Welded Carbon Steel and Carbon-Manganese Steel Boiler and Superheater Tubes.
ASTM A178 Boiler and Superheater Tubes for Electric-Resistance-Welded Carbon Steel and Carbon-Manganese Steel Boiler and Superheater Tubes. ASTM A178, identical with ASME SA-178, is the standard specification covering minimum-wall-thickness, electric-resistance-welded tubes made of carbon steel and carbon-manganese steel intended for use as boiler tubes, boiler flues, superheater flues, and safe ends.
There are three grades available:
This standard is issued under the fixed designation A 178/A 178M; 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 ( ε) indicates an editorial change since the last revision or reapproval. This specification has been approved for use by agencies of the Department of Defense. Consult the DoD Index of Specifications and Standards for specific year of issue which has been adopted by the Department of Defense.
These boilers have very good machinability; this reduces its machining costs. This alloy is resistive to corrosion in mild conditions. Moreover, these are resistive to pitting, crevice and stress corrosion cracking. These offer the best performance in elevated temperatures.
Grade | C | Mn | P | S | Si |
---|---|---|---|---|---|
Grade A Low carbon steel | 0.06-0.18 | 0.27-0.63 | 0.035 | 0.035 | ... |
Grade C Medium Carbon Steel | 0.35 Max | 0.80 Max | 0.035 | 0.035 | ... |
Grade D Manganess Steel | 0.27 Max | 1.00-1.50 | 0.03 | 0.015 | 0.10 Min. |
Chemical Composition
The steel shall conform to the requirements as to chemical composition prescribed in Table 1.
When a grade is ordered under this specification, sup- plying an alloy grade that specifically requires the addition of any element other than those listed in Table 1 is not permitted.
Product Analysis
1. When requested on the purchase order, a product analy- sis shall be made by the manufacturer or supplier from one tube per 100 pieces for sizes over 3 in. [76.2 mm] and one tube per 250 pieces for sizes 3 in. [76.2 mm] and under; or when tubes are identified by heat, one tube per heat shall be analyzed. The chemical composition thus determined shall conform to the requirements specified.
2. If the original test for product analysis fails, retests of two additional lengths of flat-rolled stock or tubes shall be made. Both retests, for the elements in question, shall meet the requirements of the specification; otherwise all remaining material in the heat or lot (Note 2) shall be rejected or, at the option of the producer, each length of flat-rolled stock or tube may be individually tested for acceptance. Lengths of flat- rolled stock or tubes which do not meet the requirements of the specifications shall be rejected.
Grade | T.S. ksi [MPa] | Y.S. ksi [MPa] | EL. in 2" min. % |
---|---|---|---|
Grade C | 60 [415] | 37 [255] | 30 |
Grade D | 70 [485] | 40 [275] | 30 |
Manufacture & Heat Treatment
The ASTM A178 Grade D steel shall be killed. ASTM A178 tubes shall be made by electric-resistance welding process. After welding, all tubes shall be heat treated at a temperature of 1650°F [900°C] or higher and followed by cooling in air or in the cooling chamber of a controlled-atmosphere furnace. Cold-drawn tubes shall be heat treated after the final cold-draw pass at a temperature of 1200°F [650°F] or higher.
Testing & Inspection
ERW tubes made from ASTM A178 steel may be tested or inspected in the following ways covering crush test, flattening test, flange test, tension test, reverse tension test, hydrostatic test, nondestructive electric test, dimension inspection, visual examination, as well as ultrasonic inspection.
NOTE 2—A lot consists of 250 tubes for sizes 3 in. [76.2 mm] and under and of 100 tubes for sizes over 3 in. [76.2 mm], prior to cutting to length.
ASTM A178 Boiler Pipes are used in many applications, including boilers, fuel lines, heat exchangers, superheaters, condensers & feedwater pipes. These pipes are made from carbon steel and can resist temperatures up to about 750 degrees Fahrenheit without cracking or weakening. Due to their anti-corrosive properties, they are suitable for use in areas exposed to the elements and can last longer than other materials.
JIS | ASTM | BS | DIN | NF | ISO | Index Number | ||||||||||||
Standard Number | Grade | Tupe | Standard Number |
Grade | Tupe | Standard Number |
Grade | Tupe | Standard Number |
Grade | Tupe | Standard Number | Grade | Tupe | Standard Number | Grade | Tupe | |
G3461 | STB340 | C | A161 | LC | C | 3059 | HFS320 | C | A49-245 | TS34e | C | C010 | ||||||
(STB35) | A192 | – | C | “ | CFS320 | C | “ | TS34c | C | |||||||||
A226 | – | C | “ | ERW320 | C | |||||||||||||
A556 | GrA2 | C | “ | CEW320 | C | |||||||||||||
A557 | GrA2 | C | “ | S1 360 | C | |||||||||||||
“ | S2 360 | C | ||||||||||||||||
“ | ERW 360 | C | ||||||||||||||||
“ | CEW360 | C | ||||||||||||||||
3606 | ERW320 | C | ||||||||||||||||
“ | CEW320 | C | ||||||||||||||||
“ | CFS320 | C | ||||||||||||||||
STB410 | C | A179 | GrC | C | 3059 | S1 440 | C | 17175 | St45.8 | C | A49-213 | TU42c | C | 2604/2 | TS9H | C | ||
(STB42) | A210 | GrA1 | C | “ | S2 440 | C | 17177 | St42.8 | C | A49-215 | TU42c | C | “ | TW9H | C | |||
A556 | GrB2 | C | “ | ERW 440 | C | A49-243 | TS42c | |||||||||||
A557 | GrB2 | C | “ | CEW 440 | C | A49-245 | TS42c | |||||||||||
3602 | HFS 410 | C | “ | TS42c | ||||||||||||||
“ | CFS 410 | C | ||||||||||||||||
“ | ERW 410 | C | ||||||||||||||||
“ | CEW 410 | C | ||||||||||||||||
3606 | ERW 440 | C | ||||||||||||||||
“ | CEW 440 | C | ||||||||||||||||
“ | CFS 440 | C | ||||||||||||||||
STB510 | C | C | 17175 | 19Mn5 | C | A49-213 | TU52C | C | 2604/2 | TS18 | C | |||||||
(STB52) | C | A49-248 | TU52C | C |
Product Name | Executive Standard | Dimension (mm) | Steel Code / Steel Grade |
---|---|---|---|
Electric-Resistance-Welded Steel Pipes | ASTM A135 | 42.2-114.3 x 2.11-2.63 | A |
Electric-Resistance-Welded Carbon Steel and Carbon-Manganese Steel Boiler and Superheater Tubes | ASTM A178 | 42.2-114.3 x 2.11-2.63 | A, C,D |
ERW and Hot-dip Galvanized Steel Pipes | ASTM A53 | 21.3-273 x 2.11-12.7 | A, B |
Pipes for Piling Usage | ASTM A252 | 219.1-508 x 3.6-12.7 | Gr2, Gr3 |
Tubes for General Structural Purpose | ASTM A500 | 21.3-273 x 2.11-12.7 | Carbon Steel |
Square Pipes for General Structural Purpose | ASTM A500 | 25 x 25-160 x 160 x 1.2-8.0 | Carbon Steel |
Mechanical tubing | ASTM A513 | 21.3-273 x 2.11-12.7 | carbon and alloy steel |
Screwed and Socketed Steel Tubes | BS 1387 | 21.4-113.9 x 2-3.6 | Carbon Steel |
Scaffolding Pipes | EN 39 | 48.3 x 3.2-4 | Carbon Steel |
Carbon Steel Tubes for General Structure Purpose | JIS G3444 | 21.7-216.3 x 2.0-6.0 | Carbon Steel |
Carbon Steel Tubes for Machine Structure Purpose | JIS G3445 | 15-76 x 0.7-3.0 | STKM11A, STKM13A |
Carbon Steel Pipes for Ordinary Piping | JIS G3452 | 21.9-216.3 x 2.8-5.8 | Carbon Steel |
Carbon Steel Pipes for Pressure Service | JIS G3454 | 21.7-216.3 x 2.8-7.1 | Carbon Steel |
Carbon Steel Rigid Steel Conduits | JIS G8305 | 21-113.4 x 1.2-3.5 | G16-G104, C19-C75, E19-E75 |
Carbon Steel Rectangular Pipes for General Structure | JIS G3466 | 16 x 16-150 x 150 x 0.7-6 | Carbon Steel |
Pipeline coating is the most consistent and successful solution for protecting ERW pipes from corrosion, from moisture, other harmful chemicals. Anti-corrosion steel pipe is processed through the preservation process, which can effectively prevent or slow down the process in the transport and use of chemical or electrochemical corrosion reaction of steel pipe. Therefore pipe anti-corrosion layer is an important barrier to prevent soil erosion. A well-known foreign scholar put forward” 3PE france protective layer”, so far, anti-corrosion methods is widely used. Coated pipes offer high resistance to corrosion on pipes and provide many benefits such as: 1. Increased Flow Capacity – A coating on pipes helps provide a smoother surface thus improving gas and liquid flow within pipes. 2. Reduced Cost – The pipeline coating increases the pipes durability so they can be deployed with minimum maintenance cost even in the harshest environments. 3. Lower energy usage – Various studies have shown that pipelines that are internally coated use less energy for pumping and compression of products through pipes. This helps in increased saving over time. 4. Clean delivery of products – The inhibitors used for the protection products can also be minimized by the use of coated pipes for delivery of products. Thus, coating of pipelines can help you in reducing your maintenance cost and at the same time providing a corrosion free reliable protection.
The basic principles of urban gas pipeline coating selection:
2.1.External Coating 2.1.1 External Epoxy Coating
2.1.2 Polyethylene Coating
2.1.3 Polypropylene Coating
2.1.4 Polyurethane Coating
2.1.5 Polyolefin Coating
2.1.6 Tape Coating
2.1.7 Bitumen Coating
2.1.8 Coal-Tar Enamel Coating
2.1.9 Concrete Weighted Coating
5:External concrete coating.
2.1.10 Marine Coating
2.1.11 Other specification
2.2. Lining 2.2.1 Epoxy Lining
2.2.2 Bitumen Lining
2.2.3 Cement Mortar Lining
2.2.4 Shop Cement Lined Piping
Pipe Coating Products
Three Layer Polyethylene (3LPE) To improve anticorrosion performance and adhesion, an additional layer of epoxy primer is sprayed onto pipe surfaces prior to the adhesive layer and Polyethylene top layer application. Three Layer Polyethylene is suitable for service temperatures from 60°C to 80°C (85°C peaks). Typical coating thickness is from 1-2 mm to 3-5 mm. Three Layer Polypropylene (3LPP) If a wider service temperature range and high stiffness is required, adhesive and top layers, applied over primer layer, are based on polypropylene instead of polyethylene. Three Layer Polypropylene is suitable for service temperatures up to 135 °C (140°C peaks). Typical coating thickness is from 1-2 mm to 3-5 mm. Three Layer Polypropylene and Polyethylene Three Layer applications involve a thermoplastic coating applied to steel pipelines as a form of anticorrosion protection. This mechanical resistance is appropriate when the risk of particularly severe coating damages exist. The Three Layer process involved several steps. First, the pipe surface is blast cleaned to remove any external residue from the mill or storage. It is then heated and sprayed with a Fusion Bond Epoxy (FBE) primer followed by the application of an adhesive copolymer and polyolefin polymers that are wrap extruded, one over the other. Field applied products
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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.