Titanium Screwed Flange are also known as threaded flanges , and it is having a thread inside the flange bore which fits on the pipe with matching male thread on the pipe. This type of joint connection is Speedy and simple but not suitable for high presser and temperature applications. Threaded Flanges are mostly used in utility services such as air and water.
We are the leading Manufacturers, Supplier and Exporters of Screwed/Threaded Flanges using high quality raw materials. These Flanges is used to connect other threaded components in low pressure, non-critical applications.
These flanges can be attached to the pipe without welding and applicable in highly volatile areas where welding is hazardous. These Flanges widely used in various applicaions industry. These Flanges is available in various size, grades, Specification & thickness as per the clients requirments. These flanges are offered at market leading rates.
Titanium : Grade: Gr.1 (3.7025) , Gr.2 (3.7035) , Gr.3:(3.7055) , Gr.5(3.7164/65), Gr. 7(3.7235) , Gr. 11 (3.7225) |
C | Fe | H | N | O | Ti |
---|---|---|---|---|---|
max | max | max | max | max | max |
0.1 | 0.2 | 0.015 | 0.03 | 0.18 | 99.5 |
Hardness, Brinell | 120 | 120 | annealed |
---|---|---|---|
Hardness, Knoop | 132 | 132 | Estimated from Brinell. |
Hardness, Rockwell B | 70 | 70 | annealed |
Hardness, Vickers | 122 | 122 | Estimated from Brinell. |
Tensile Strength, Ultimate | 240 MPa | 34800 psi | |
Tensile Strength, Yield | 170 - 310 MPa | 24700 - 45000 psi | |
Elongation at Break | 24 % | 24 % | |
Reduction of Area | 35 % | 35 % | |
Modulus of Elasticity | 105 GPa | 15200 ksi | In Tension |
Compressive Modulus | 110 GPa | 16000 ksi | |
Poisson's Ratio | 0.37 | 0.37 | |
Charpy Impact | 310 J | 229 ft-lb | V-notch |
Shear Modulus | 45 GPa | 6530 ksi |
Stainless Steel : Grade: 304 (1.4301), 304L (1.4307), 304H (1.4948), 309 (1.4828), 309S, 310, 310S (1.4845) , 316 ( 1.4401), 316H, 316L( 1.4404 /1.4432) , 317, 317L (1.4438), 321 (1.4541), 321 H(1.4878), 347 (1.4550), 347H (1.4961), 904L (1.4539) Duplex Steel: Grade: 2205 (1.4507) Super Duplex Steel: Grade: 2507 (UNS S32750) (1.4410) (UNS S32750) Inconel : Grade: Inconel 600 (2.4640), Inconel 601 (2.4851), Inconel 625 (2.4856), Inconel 718(2.4668) Incoloy : Grade: Incoloy 800 (2.4958), Incoloy 800H, Incoloy 800HT Nickel : Grade: Nickel 200, Nickel 201 Monel : Grade: Monel 400 ( 2.4360), Monel K500, Monel R-405 Hastalloy : Grade: Hastalloy B2, Hastalloy B3, Hastalloy C22, Hastalloy C276, Hastalloy X |
The manufacturing process of flange mainly is divided into forging, casting, cutting and rolling. .
The casting and forging flanges have advantages that the blanks of them have accurate shape, size and low costs and only need simple process. But forging flanges have manufacturing defects such as blowholes, cracks, etc and have not very smooth internal organization streamline. The obvious advantages of forging flanges are that they can be forged in various shapes and they have low costs. .
Forging flanges generally have lower carbon content than the casting flanges and are not easy to rust. They have smooth streamline, uniform internal organization, and better mechanical performance than that of casting flanges. There are no defects, such as blowholes and cracks existing in the casting flanges. Forging flanges are able to withstand higher shear and drawing forces than casting flanges. However, if adopting improper forging process, it will also cause appearance of large, uneven grains and solidification cracking phenomenon, resulting in higher cost than the casting flanges. .
We can distinguish between the casting flanges and forging flanges from the different production process. To take the centrifugal flange as an example, it is a kind of casting flange. Centrifugal flanges are produced by a precision casting method, which makes the flanges’ organization smaller than those commonly produced by sand casting and improves the quality of flanges, making fewer occurrences of loose tissue, pore, sand hole etc.
Cutting process refers to producing flanges by directly cutting a round plate with the inner diameter, outer diameter and thickness which can be further processed later from the middle plate, and then processing the bolt hole and waterline. The maximum diameter of such flanges is limited by the width of the middle plate.
Cutting process refers to producing flanges by cutting stripes from the middle plate and then rolling them into round shape. This process is mainly used for the production of large flange. After the rolling process, weld and then flatten the round shape, and finally process the serrated spiral finish and bolt hole.