Tricon Steel and Alloys stand tall as a distinguished name in the realm of alloy steel pipe manufacturing and supply in India. As a prominent player in the industry, the company has earned a reputation for delivering high-quality alloy steel pipes that cater to diverse industrial applications.
With a commitment to excellence, Tricon Steel and Alloys has positioned itself as one of the leading alloy steel pipe manufacturers in India. The company boasts state-of-the-art manufacturing facilities that adhere to stringent quality control measures, ensuring that each product meets international standards. This dedication to quality has made Tricon a trusted name among customers seeking reliable alloy steel pipes for their projects.
As a reliable alloy steel pipe supplier in India, Tricon Steel and Alloys caters to the ever-growing demand for robust and durable pipes in various sectors, including oil and gas, petrochemicals, power generation, and more. The extensive product range offered by the company includes alloy steel pipes of different specifications, sizes, and grades, providing customers with a comprehensive solution for their specific requirements.
Tricon's commitment to customer satisfaction goes beyond just delivering products. The company prioritizes understanding the unique needs of its clients and ensures that the supplied alloy steel pipes not only meet but exceed expectations. This customer-centric approach has contributed significantly to Tricon's success in the competitive market.
In addition to manufacturing and supplying alloy steel pipes, Tricon Steel and Alloys actively invests in research and development to stay ahead of industry trends. This commitment to innovation enables the company to introduce cutting-edge products that align with evolving customer demands and industry standards.
As the demand for high-performance alloy steel pipes continues to grow, Tricon Steel and Alloys remain at the forefront of the industry, providing top-notch solutions to clients across India. With a focus on quality, reliability, and customer satisfaction, Tricon Steel and Alloys solidifies its position as a premier alloy steel pipe manufacturer and supplier in the dynamic landscape of the Indian steel industry.
Alloy steel pipes play a pivotal role in various industries, offering a combination of strength, corrosion resistance, and versatility. When considering alloy steel pipes, understanding their dimensions and weight is crucial for proper installation and performance. The Alloy Steel Pipe Schedule Chart provides a comprehensive guide to the pipe's wall thickness, aiding in selecting the appropriate pipe for specific applications.
Additionally, the Alloy Steel Pipe Weight Chart is instrumental in determining the weight per unit length of the pipe. This information is vital for transportation, handling, and structural considerations during installation. The weight chart assists in estimating the overall load-bearing capacity and ensures compliance with project specifications.
Whether in oil and gas, power generation, or construction, the Alloy Steel Pipe Schedule and Weight Charts are valuable resources for engineers and professionals. These charts enable precise planning and execution, ensuring that alloy steel pipes meet the required standards and provide reliable performance in diverse industrial applications. Here are some commonly referenced alloy steel pipe specifications:
ASTM A213 / A213M - Standard Specification for Seamless Ferritic and Austenitic Alloy-Steel Boiler, Superheater, and Heat-Exchanger Tubes: This specification covers seamless ferritic and austenitic alloy-steel tubes designed for high-temperature service, such as in boiler systems, superheaters, and heat exchangers. Alloy Steel Pipe Grades commonly specified under this standard include T11, T22, T91, and others, each indicating specific alloy compositions suitable for different applications.
ASTM A335 / A335M - Standard Specification for Seamless Ferritic Alloy-Steel Pipe for High-Temperature Service: ASTM A335 specifies seamless ferritic alloy-steel pipe intended for high-temperature service. These pipes are commonly used in industries such as oil and gas, power generation, and chemical processing. Alloy Steel Pipe Grades like P11, P22, P91, and others are defined in this specification, with each grade denoting a specific alloy composition and heat treatment.
ASTM A691 / A691M - Standard Specification for Carbon and Alloy Steel Pipe, Electric-Fusion-Welded for High-Pressure Service at High Temperatures: This specification covers carbon and alloy steel pipes that are electric-fusion-welded with added filler metal. It is designed for high-pressure service at elevated temperatures. ASTM A691 includes various classes and grades, each indicating specific requirements for alloy composition, heat treatment, and mechanical properties.
ASTM A199 / A199M - Standard Specification for Seamless Cold-Drawn Intermediate Alloy-Steel Heat-Exchanger and Condenser Tubes: This specification covers cold-drawn alloy-steel tubes for use in heat exchangers and condensers. It is suitable for applications requiring high-pressure tubing with enhanced heat transfer capabilities. Alloy Steel Pipe Grades like T5, T9, T11, and T22 are specified under ASTM A199 for different heat exchanger and condenser applications.
ASTM A200 / A200M - Standard Specification for Seamless Intermediate Alloy-Steel Still Tubes for Refinery Service: ASTM A200 outlines the requirements for seamless intermediate alloy-steel tubes used in petroleum refineries for still and boiler service. This specification includes various Alloy Steel Pipe Grades, such as T5, T9, and T22, each tailored to withstand the harsh conditions encountered in refinery applications.
DIN 17175 - Seamless Tubes of Heat-Resistant Steels: This German standard specifies the technical delivery conditions for seamless steel tubes of heat-resistant steels for elevated temperature service. DIN 17175 includes various grades, such as 13CrMo44, 10CrMo910, and 15Mo3, which are commonly used in the manufacturing of tubes for boilers and heat exchangers.
These alloy steel pipe specifications provide comprehensive guidelines for the manufacturing, testing, and performance of tubes and pipes. Manufacturers and end-users rely on these standards to ensure the integrity and reliability of these critical components in diverse industrial applications.
Pipe Specifications | ASTM A335 / ASME SA335 |
Tube Specifications | ASTM A213 / ASME SA213 |
Dimensions | ANSI/ASME B36.19M, ANSI/ASME B36.10M |
Seamless Pipe & Tube Size | 1/2″ NB – 16″ NB |
Tube Outside Diameter | 6.00 mm OD up to 914.4 mm OD, Sizes up to 24” NB available Ex-stock, OD Size Steel Tubes available Ex-stock |
Thickness | 0.35 mm – 50 mm |
Specialized in | Large Diameter Pipe Size |
Schedule | SCH5, SCH10, SCH20, SCH30, SCH40, STD, SCH80, SCH 80S, SCH60, SCH80, SCH120, SCH140, SCH160, SCH XXS, SCH XS |
Type | Seamless Pipes, ERW Pipes, Welded Pipe |
Form | Round, Square, Hydraulic, U Shape, Rectangular, Pan Cake Coils, Coiled, Hex, Honed, Etc |
Length | Single Random, Double Random & Required Length. |
End | Plain End, Beveled End, Treaded End |
The Rolling and Welding Stage
To begin our process, we first need to go through the rolling and welding stage. The stainless steel is placed through a checking process and cut at the edges in this stage.
Cleaning and Warming Stage
The rolled stainless steel pipes thus manufactured are cut to the required lengths depending upon the industrial demand.
Cold-Drawing Stage
Sometimes, the required size isn’t obtained when the steel is brought through the mill directly. When using the cold-drawing process, the desired size is achieved when the pipes and tubing are coated with oxalic and soap solution and dragged over die plugs—the oxalic and soap solution help reduce friction when going through the cold cycle.
The Finishing Process
The final process is the finisher. Once the process of manufacturing stainless steel pipes and tubing is completed, you’ll now have to take them to a jet printer.
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Alloy steel tubes come in various types, each designed to meet specific requirements in different industrial applications. These tubes are crafted from alloyed steel, which is a combination of iron and other elements, such as chromium, molybdenum, nickel, or vanadium. The addition of these elements imparts unique properties to the steel, making alloy steel tubes suitable for a wide range of challenging environments. Here are some common types of alloy steel tubes:
Seamless Alloy Steel Tubes: Seamless alloy steel tubes are manufactured without any welding seams, resulting in a more uniform structure with enhanced strength and corrosion resistance. The seamless manufacturing process involves piercing a solid steel billet to form a hollow tube. These tubes are widely used in high-temperature and pressure applications, such as in power generation plants, chemical processing, and oil and gas industries. ASTM A213 and ASTM A335 are common specifications for seamless alloy steel tubes, covering various alloy compositions to meet different service conditions.
ERW (Electric Resistance Welded) Alloy Steel Tubes: ERW alloy steel tubes are produced by welding together the edges of a flat strip of steel, forming a cylindrical shape. This cost-effective manufacturing process is suitable for a variety of applications. ERW tubes find applications in industries like construction, infrastructure, and general engineering. They are also used in oil and gas pipelines, where cost efficiency and moderate strength are important. ASTM A335 and ASTM A691 are commonly used specifications for ERW alloy steel pipes, ensuring the necessary strength and corrosion resistance.
Alloy Steel Boiler Tubes: Alloy steel boiler tubes are specifically designed to withstand high temperatures and pressures in boiler systems. They are crucial components in power generation plants and industrial boilers. These tubes are used in the construction of superheaters, reheaters, and water walls in boilers. They provide excellent resistance to oxidation and corrosion at elevated temperatures. ASTM A213 and ASTM A335 are often specified for alloy steel boiler tubes.
Alloy Steel Heat Exchanger Tubes: Heat exchanger tubes made of alloy steel are designed to efficiently transfer heat between two fluids. They are crucial components in various industrial processes, such as chemical manufacturing and HVAC systems. Alloy steel heat exchanger tubes are used in the construction of shell-and-tube heat exchangers, where they provide high thermal conductivity and corrosion resistance. ASTM A213 and ASTM A335 are commonly used for alloy steel heat exchanger tubes.
Alloy Steel Hydraulic Tubes: Alloy steel hydraulic tubes are designed for hydraulic and pneumatic applications, where durability, strength, and resistance to wear are essential. These tubes find use in hydraulic systems for various industries, including construction equipment, automotive applications, and heavy machinery. While specific alloy steel grades may vary, common choices include chromium-molybdenum alloys for enhanced strength and corrosion resistance.
Alloy Steel Aircraft Tubes: Alloy steel tubes used in aircraft applications must meet stringent requirements for weight, strength, and corrosion resistance. These tubes play a crucial role in the construction of aircraft structures and components. Aircraft tubes are used in the fabrication of airframes, landing gear, and other critical components where a balance between strength and weight is essential. Specific alloy steel pipe grades for aircraft tubes depend on the aircraft's design and requirements.
Alloy steel pipes are composed of a combination of iron and various alloying elements to impart specific mechanical, thermal, and corrosion-resistant properties. Alloy Steel Pipe chemical composition plays a crucial role in determining their suitability for different applications. The most common alloying elements include chromium, molybdenum, nickel, vanadium, and others, each contributing distinct characteristics to the steel. Here's an overview of the typical chemical composition of alloy steel pipes:
Chromium (Cr): Chromium is a key alloying element in many alloy steels, providing corrosion resistance, high-temperature strength, and hardenability. Common chromium-containing alloy steels include grades like 5Cr, 9Cr, and 12Cr.
Molybdenum (Mo): Molybdenum enhances the strength and corrosion resistance of alloy steel, particularly at elevated temperatures. Alloy steels with molybdenum, such as grades T1, T9, and T91, are often employed in high-temperature applications like boiler tubes.
Nickel (Ni): Nickel contributes to improved toughness, impact resistance, and high-temperature strength. Nickel-containing alloy steels, like grades such as 20Ni-25Cr, are utilized in applications requiring a combination of strength and corrosion resistance.
Vanadium (V): Vanadium enhances the strength, toughness, and wear resistance of alloy steel. Some alloy steels, including those with vanadium, are used in applications like tool steel and high-strength low-alloy (HSLA) steel.
Manganese (Mn): Manganese is often added to improve hardenability and strength in alloy steel. It is a common alloying element in various grades, such as 15Mo3 and 16Mn, used in pressure vessel and structural applications.
Tungsten (W): Tungsten contributes to hardness and wear resistance in high-speed tool steels. Alloy steels with tungsten are employed in applications requiring cutting tools and wear-resistant components.
Carbon (C): Carbon is a fundamental element in steel and contributes to its strength and hardness. The carbon content in alloy steel pipes varies, and specific grades are selected based on the desired balance between strength and machinability.
Silicon (Si): Silicon is often added to improve the deoxidation and strength of alloy steel. It is a common alloying element in various grades used in structural applications and automotive components.
The specific chemical composition of alloy steel pipes is defined by industry standards such as ASTM and DIN. These standards specify the allowable ranges for each alloying element, ensuring consistency and reliability in the manufacturing process. Alloy steel pipes with well-defined chemical compositions are tailored to meet the diverse requirements of industries such as oil and gas, power generation, aerospace, and construction, where the performance of materials under challenging conditions is critical. Alloy Steel Pipe Manufacturers in India carefully control the alloying elements to achieve the desired properties, ensuring that alloy steel pipes meet the stringent standards and specifications set for their intended applications.
Alloy steel pipes exhibit distinctive mechanical characteristics that make them well-suited for a variety of demanding applications across industries. The mechanical properties of alloy steel pipes are crucial factors influencing their strength, toughness, and performance under different conditions. Here are key mechanical characteristics:
High Tensile Strength: Alloy steel pipes are known for their high tensile strength, making them capable of withstanding heavy loads and pressure. This property is essential in applications such as oil and gas pipelines and structural components.
Excellent Toughness: Alloy steels demonstrate excellent toughness, resisting fracture or deformation even under extreme conditions. This is particularly important in applications where impact resistance is crucial, such as in structural elements and components subject to dynamic loading.
Good Ductility: Ductility refers to a material's ability to undergo deformation without breaking. Alloy steel pipes exhibit good ductility, allowing for easy shaping and forming during the manufacturing process. This property is advantageous in applications that require intricate shapes or bending.
High Yield Strength: Alloy steels typically have a high yield strength, indicating the amount of stress the material can withstand without permanent deformation. This characteristic is beneficial in applications where stability under load is critical, such as in pressure vessels and boilers.
Superior Hardness: Certain alloy steel pipe grades are known for their superior hardness, a property crucial in applications involving wear and abrasion resistance. Alloy steel pipes with enhanced hardness are commonly used in tools, cutting equipment, and wear-resistant components.
Elevated Temperature Performance: Many alloy steels are designed to maintain their mechanical properties at elevated temperatures, making them suitable for applications in high-temperature environments. This is particularly important in industries like power generation and petrochemical processing.
Corrosion Resistance: Some alloy steels exhibit enhanced corrosion resistance, protecting against degradation in aggressive environments. This property is vital in applications where exposure to corrosive substances is common, such as in chemical processing and offshore structures.
Fatigue Resistance: Alloy steel pipes often display good fatigue resistance, meaning they can withstand cyclic loading and repeated stress without failure. This property is crucial in components subjected to fluctuating loads, such as in automotive and aerospace applications.
These mechanical characteristics are determined and specified by industry standards such as ASTM and DIN, ensuring that alloy steel pipes meet the required performance standards for their intended applications. Alloy Steel Pipe Manufacturers in India carefully control the alloy composition and employ specific heat treatments to achieve the desired mechanical properties, ensuring that alloy steel pipes deliver reliable and consistent performance in a wide range of industrial settings.
We also supply Alloy Steel Pipe at the best price. You can check our latest Alloy Steel Pipes price list. Contact Tricon Steel & Alloys today for a best offer & competitive quotation Of Alloy Steel Pipe.
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