Ni-Hard Wearback Pipes
Abrasion Resistant Cast Iron Pipe
A bimetal clad pipe tee, also known as a bimetallic clad pipe tee, is a type of pipe fitting used in piping systems.
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A bimetal clad pipe tee is made by bonding two different metal layers together. The inner layer, which comes into contact with the fluid being transported, is typically made of a highly resistant material such as ceramic or high-chromium alloy. This inner layer provides excellent resistance to wear caused by abrasive substances in the fluid.
The outer layer of the bimetal clad pipe tee is usually made of a different material, often carbon steel or stainless steel. This outer layer provides structural strength and support to the tee.
Bimetal clad pipe tee with flange
Bimetal clad pipe tee with flange
The use of a bimetal clad pipe tee offers several advantages in piping systems, including:
Proper installation and regular maintenance are essential to ensure the optimal performance and longevity of the bimetal clad pipe tee. It is important to follow the manufacturer's guidelines for installation procedures and maintenance practices.
Regular inspection should be conducted to detect any signs of wear, corrosion, or damage. If any issues are identified, appropriate maintenance or replacement should be carried out to prevent leaks or failures in the piping system.
| Flexure Strength MN/㎡ |
Tensile Strength MN/㎡ |
Elongation % |
Cross Section Stretch Ratio % |
Impact Toughness J/c㎡ |
Hardness of Wearable Layer HRC |
Hydrostatic Testing Pressure Mpa |
|---|---|---|---|---|---|---|
| >610 | >700 | 5 | 5.1 | >15 | >38 | 5.6-12.9 |
| Standard | Item | Grade | Chemical composition (%) | Tensile requirements | Hardness(HB) | |||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| C | Si | Mn | P | S | Ni | Cr | Mo | Cu | Thickness(mm) | Tensile strength(Mpa) | Elongation(%) | Heat treatment | ||||
| GB | 8263 | KmTBNi4-Cr2-DT | 2.7-3.2 | 0.3-0.8 | 0.3-0.8 | ≦0.15 | ≦0.1 | 3.0-5.0 | 2.0-3.0 | 0.0-1.0 | - | - | - | - | - | - |
| ASTM | A532 | I BNiCr-LC | 2.4-3.0 | ≦0.8 | ≦2.0 | ≦0.3 | ≦0.15 | 3.3-5.0 | 1.4-4.0 | ≦1.0 | - | ≧200 | - | - | - | ≦550 |
| DIN | 1695 | G-X260-NiCr42 | 2.6-2.9 | 0.2-0.8 | 0.3-0.7 | - | - | 3.5-5.0 | 1.4-2.4 | ≦0.5 | - | - | ≧320 | - | - | ≦500 |
| GB | 8263 | KmTBNi4-Cr2-GT | 3.2-3.6 | 0.3-0.8 | 0.3-0.8 | ≦0.15 | ≦0.1 | 3.0-5.0 | 2.0-3.0 | 0.0-1.0 | - | - | - | - | - | - |
| ASTM | A532 | I ANCr-HC | 2.8-3.6 | ≦0.8 | ≦1.3 | ≦0.3 | ≦0.15 | 3.3-5.0 | 1.4-4.0 | ≦1.0 | - | ≧200 | - | - | - | ≦550 |
| DIN | 1695 | G-X330-NiCr42 | 3.0-3.6 | 0.2-0.8 | 0.3-0.7 | - | - | 3.3-5.0 | 1.4-2.4 | ≦0.5 | - | - | ≧280 | - | - | ≦690 |
| GB | 8263 | KmTBCr9-Ni5Si2 | 2.5-3.6 | 1.5-2.2 | 0.3-0.8 | ≦0.15 | ≦0.1 | 4.5-6.5 | 8.0-10.0 | 0.0-1.0 | - | - | - | - | - | - |
| ASTM | A532 | I DNiHCr | 2.5-3.6 | ≦2.0 | ≦2.0 | ≦0.1 | ≦0.15 | 4.5-7.0 | 7.0-11.0 | ≦1.5 | - | ≧300 | - | - | - | ≦500 |
| DIN | 1695 | G-X300Cr-NSi952 | 2.5-3.5 | 1.5-2.2 | 0.3-0.7 | - | - | 4.5-6.5 | 8.0-10.0 | ≦0.5 | - | - | 500-600 | - | - | ≦690 |
| GB | 8263 | KmTBCr15-Mo2-GT | 2.8-3.5 | ≦1.0 | 0.5-1.0 | ≦0.1 | ≦0.06 | 0.0-1.0 | 13.0-18.0 | 0.5-3.0 | 0.0-1.2 | - | - | - | - | - |
| ASTM | A532 | ⅡB15%Cr-Mo-HC | 2.0-3.0 | ≦1.5 | ≦2.0 | ≦0.1 | ≦0.06 | ≦2.5 | 14.0-18.0 | 1.0-3.0 | ≦1.2 | ≧75 | - | - | H | ≦600 |
| DIN | 1695 | G-X300-CrMo153 | 2.3-3.6 | 0.2-0.8 | 0.5-1.0 | - | - | ≦0.7 | 14.0-17.0 | 1.0-3.0 | ≦1.2 | - | ≧450 | ≦690 | H | - |
| ASTM | A532 | Ⅱ020%-CrMo-LC | 2.0-3.3 | 1.0-2.2 | ≦2.0 | ≦0.1 | ≦0.06 | ≦1.5 | 18.0-23.0 | ≦2.0 | ≦1.2 | ≧200 | - | - | H | ≦600 |
| DIN | 1695 | G-X260Cr-MoNi2021 | 2.3-2.9 | 0.2-0.3 | 0.5-1.0 | - | - | 0.8-1.2 | 18.0-22.0 | 1.4-2.0 | - | - | ≧450 | - | H | ≦690 |
| GB | 8263 | KmTBCr20-Mo2Cu1 | 2.0-3.0 | ≦1.0 | 0.5-1.0 | ≦0.1 | ≦0.06 | 0.0-1.5 | 18.0-22.0 | 1.5-2.5 | 0.8-1.2 | - | - | - | - | - |
| ASTM | A532 | ⅡA-25%Cr | 2.0-3.0 | ≦1.5 | ≦2.0 | ≦0.1 | ≦0.06 | ≦2.5 | 23.0-30.0 | ≦3.0 | ≦1.2 | ≧200 | - | - | - | ≦600 |
| DIN | 1695 | G-X260-Cr27 | 2.3-2.9 | 0.5-1.5 | 0.5-1.5 | - | - | ≦1.2 | 24.0-28.0 | ≦1.0 | - | - | ≧560 | - | - | ≦690 |
| GB | 8263 | KmTBCr26 | 2.3-3.0 | ≦1.0 | 0.5-1.0 | ≦0.1 | ≦0.06 | 0.0-1.5 | 23.0-28.0 | 0.0-1.0 | 0.0-2.0 | - | - | - | - | - |
| ASTM | A532 | Ⅲ A-25%Cr | 2.0-3.3 | ≦1.0 | ≦2.0 | ≦0.1 | ≦0.06 | ≦2.5 | 23.0-30.0 | ≦1.5 | ≦1.2 | ≧200 | - | - | H | ≦600 |
| DIN | 1695 | G-X300Cr-Mo271 | 3.0-3.5 | 0.2-1.0 | 0.5-1.0 | - | - | - | 23.0-28.0 | 1.0-2.0 | ≦1.2 | - | ≧450 | - | H | ≦690 |
Bimetal wear resistant pipe adopts centrifugal casting technology in the production process of straight pipe.
This technology is to fuse and shape both metals in liquid state, realizing the purpose of real metallurgical bonding. The shear strength of the binding layer is higher than that of the metal itself, and completely realizes the mechanical complementarity between base layer and wear resistant layer.
Bimetal wear resistant pipe, including: double metal wear-resisting straight pipe and double metal wear-resisting bend, double metal wear tee, double metal wear resistance reducer adopts the pipe fittings such as vacuum suction casting composite process, its advanced technology, effectively solve the problem of the bent pipe cannot be composite, bending and other various special-shaped pipe can do the whole compound, don't change the material flow in the pipe bending trajectory, reduce resistance material conveying.
The outer wall of the centrifugal pipe is made of carbon steel, which ensures that the bimetal wear-resistant pipe has high mechanical strength and impact resistance.The inner lining wear resistance layer adopts the anti-wear alloy steel series independently developed by our company. The steel mainly adds alloy such as cr-ni-mo-cu-re and so on. Through the tempering heat treatment process, the alloy steel has strong wear resistance and corrosion resistance, high mechanical strength and impact resistance.
The whole set of process of our company is the first in China, which fills the blank of anti-corrosion and wear-resistant industrial pipeline in China and has reached the international advanced level. It has been widely used in mining, metallurgy, coal, electric power and other industries, and is an ideal wear-resistant pipeline.
The base material is carbon steel or low alloy steel. Clad pipes comply with the most stringent requirements of strength and corrosion resistance. The carbon steel outer pipe (backing steel or base metal) complies with the static requirements of strength and durability whereas the high alloyed inside pipe provides protection against corrosion.
Metallurgically bonded bimetal clad pipe
Self-propagating High-temperature Synthesis (SHS) process
High-chromium cast iron represents the third generation of white cast irons, developed from conventional Ni-Hard alloys.
Axial fans move air parallel to the shaft axis. They are widely used in ventilation, cooling and industrial exhaust systems where high flow rates at low to medium pressures are required.
(1) Centrifugal casting technology enables the molten steel to solidify and form under the gravity condition, which is dozens of times higher than conventional casting. It solves the problem of loose inside the casting tube billet, has high metal density, and has good discharge and exhaust effect.
(2)The size accuracy of centrifugal cast pipe is high and the wall thickness is even, which provides a favorable guarantee for the size accuracy of subsequent processed products.
(3)Centrifugal casting process has high flexibility for the production of steel pipes of small batch, multiple varieties and specifications, high quality and high value-added steel.
CRA basically means corrosion resistant alloy.
It’s a material that is built for cladding because its main purpose is to enhance a pipe’s resistance to corrosion.
Pipe elbow cladding is the process of applying a cladding material to elbow pipes.
It’s done on a more careful manner than the usual.
This is because elbow pipes can change throughout the entirety of the process.
Particularly, the process of pipe cladding benefits the oil and gas industry the most.
However, it can also be used by other industries such as:
Pipe lining is the process of prolonging the lifespan of pipes.
It can also be used, however, to restore a pipe from natural damages such as:
Pipe lining and pipe cladding are processes that are far from each other.
Lining is the process of mechanically bonding materials to pipes for restoration. Some of the uses of pipe lining include:
Cladding is the procedure of metallurgical bonding of clad materials to pipes. Some of the major uses of pipe cladding include:
There are a lot of companies that utilize state-of-the-art pipe cladding equipment.
We have cutting-edge technology that can complete projects ahead of time.
Some of the most notable features that our pipe cladding equipment have include:
When you partner with Sunny Steel, you can stop worrying about meeting deadlines thanks to our responsive and timely service. You'll also say goodbye to unnecessary shopping around. Instead, you'll get white glove service from an expert who understands your needs and can get you the materials you need quickly.