These A234 WPB B16.9 Elbows are used in pipe system construction. We are manufacturing ASTM A234 WPB Elbow from pipes using “mandrel” method which allows the pipe to expand and bend simultaneously.
These A234 WPB SCH 80 Elbow are also available in a wide size range. The purpose to use a ASTM A234 gr WPB elbow is to change direction or flow in a piping system.
There are 5 most common ASTM A234 WPB Elbow are in mainly in demand, the 45¡ã, 90¡ã and 180¡ã elbows, all three in the “long radius” version, and in addition the 90¡ã and 180¡ã elbows both in the “short radius” version.
In our Mumbai Facotry, we produce long radius (LR, LRE) A234 Pipe Elbow the radius of curvature is 1.5 times the diameter (R=1.5D).
ASTM A234 WPB Elbow is one of the most used forms of pipe fittings. An elbow is a connector shaped like an elbow and allows for directional transformation in fluid flow.
Chrome-Molybdenum ASTM A234 WPB Reducer Elbow for the petrochemical, nuclear, gas and oil industries, Norsok Ed4, BP, Saudi Aramco, SABIC, and Shell approved, producing ASTM A234 WPB alloy steel butt welding pipe fittings.
ASTM A234 WPB short radius in accordance with ASME B16.9.Carbon steel pipe fittings manufactured to ASMT A234 are usually furnished in the butt-welding form in accordance with ASME B16.9 or ASME B16.49.
We also accept all orders of CS Elbow A234 WPB up to and including 90 degree to suit your requirements.
All SA234 WPB Elbow are manufactured in India and produced from strictly European sourced raw material. All ASTM A234 Elbow & Elbow A234 Wpc are manufactured from plate, pressed in two halves with two weld seams.
A234 WPB Elbow is produced and supplied in the butt welded form. SA234 WPB Elbow usually comes in either of three angles; 22.5, 45 or 90 degrees.
ASTM A234 WPB Elbow is a standard specification for Piping Fittings of Wrought Carbon Steel and Alloy Steel suitable for for Moderate and High Temperature Service.
The deformation activation energy is low during superplastic deformation, and the process may be controlled by diffusion.
MonelK-500 alloy has a strong aging cracking tendency after large cold deformation. Cracks initiate on the surface and propagate towards the center. There are both transcrystalline and intercrystalline forms.
The superposition of residual stress caused by cold working and aging thermal stress, as well as the preferential embrittlement of the surface layer at the initial stage of aging, are the main reasons for aging cracking of Monel K500 alloy.
Monel K500 alloy has excellent corrosion resistance, and has higher strength and hardness than Monel 400. This is due to the addition of elements such as Al and Ti to the alloy, and after a certain heat treatment, there are dispersed intermetallic compounds on the substrate.
Monel K500 has about three times the yield strength and twice the tensile strength of Monel 400, and higher mechanical properties can be obtained by cold working or age hardening. Monel K500 alloy has the same corrosion resistance as Monel 400 alloy.
Monel K500 alloy has the same corrosion resistance as Monel 400 alloy.
Generally, the corrosion resistance of Monel K500 in solid solution is basically the same as that of Monel 400 alloy, so the corrosion resistance data of Monel 400 can be applied to Monel K500 alloy. Due to its low corrosion rate and high strength in flowing seawater, the alloy is particularly suitable for manufacturing seawater corrosion-resistant centrifugal pump shafts.
Monelk500, also known as UNS N05500, has the same corrosion resistance as monel400, but has higher mechanical strength and hardness. It has good corrosion resistance and long-term organizational stability.
Monel k500 has good corrosion resistance and long-term organizational stability.
Adding a small amount of Mg to Monel K-500 alloy can increase the grain boundary bonding force and improve high temperature plasticity.
The high-temperature plasticity of the experimental alloy added with trace amounts of Mg, Cr and Co is obviously improved, and it exhibits certain superplasticity. At 1010¡æ, the strain rate sensitivity index m is 0.32, and the maximum elongation is 240%.
Using the fracture work theory calculation of impurity elements segregation at grain boundaries, it is shown that Mg, Cr and Co can improve the grain boundary bonding force of Ni-Cu alloy, so they can improve the high temperature plasticity of Monel K-500 alloy.
Typical applications for alloy 800 and 800H are – Heat exchangers and process piping; carburizing fixtures and retorts; furnace components; electric range heating-element sheathing; extruded tubing for ethylene and steam methane reforming furnaces; ammonia effluent coolers.
The principle di?erence between alloys 800H and 800HT is the restricted aluminum and titanium content in 800HT, which results in higher creep and stress rupture properties.
Alloy 800H/800HT is frequently used in applications that involve long-term exposure to elevated temperatures where resistance to oxidation, carburization and other types of elevated temperature corrosion is required.
HT PIPE is a leading supplier of Alloy 800 and other high-quality special metal alloys with decades of experience and extensive specifications.
Incoloy 800 is an alloy whose primary constitution is made up of nickel, iron, and chromium. This particular alloy, unlike the former, has less than 50% nickel content in its chemical composition. Aside from their chemical makeup, the other points of distinction for both the alloys are their use in a specific set of applications or industries.
Incoloy 800 is an alloy with a higher content of iron. Due to the alloy having a higher content of ferrous, and lower content of nickel, the cost of Inconel 800 becomes low.
