Titanium Weld Neck Flange with Gr2 Grade and DN15-DN1200 Dimensions Featuring

ASME B16.5 is a standard that provides the requirements for pipe flanges and flanged fittings used in piping systems, typically in industries such as chemical, petrochemical, power generation, and oil & gas. The Grade 1, Grade 2, and Grade 5 classifications, along with the Raised Face (RF) design, are relevant to different types of Weld Neck Flanges (WNRF), specifically in the Class 300 pressure rating for piping systems. Here's an overview of these components:

Enhanced Strength: The design of a weld neck flange, with its tapered neck that gradually transitions into the pipe, provides a strong, seamless connection. This tapering minimizes the stress concentration at the joint and ensures a smooth transfer of pressure and stresses from the pipe to the flange.

No Stress Risers: Because of the continuous taper from the neck to the flange, the weld is less prone to the formation of stress risers, reducing the risk of failure under pressure.

Smooth Transition: The gradual transition of the weld neck flange ensures a smooth inner bore, which minimizes turbulence and reduces the likelihood of leaks. This smoothness is particularly important in high-pressure or high-temperature systems where leakage could have serious safety and operational consequences.

Pressure Distribution: The design allows for better distribution of pressure, especially in critical applications where leaks would be hazardous or costly.

Reusability: Weld neck flanges can be reused in many cases because the flange and pipe are welded together in a way that can be easily cut and re-welded if necessary. This is particularly valuable in systems where disassembly and reassembly might be required over the years.

Less Likely to Fail: Due to the strong connection and high resistance to fatigue, weld neck flanges generally have a longer lifespan and require less frequent maintenance.

Variety of Pressure Ratings: Weld neck flanges come in various pressure ratings, making them suitable for a wide range of applications, from low-pressure to high-pressure systems.

Adaptable to Different Sizes and Materials: They can be used in systems with different pipe sizes and materials, making them versatile for many industrial applications, including high-temperature, high-pressure, and corrosive environments.

Variety of Welding Options: The design of the weld neck flange allows for different types of welding methods, such as butt welding or socket welding, depending on the specific requirements of the application.

Corrosion Resistance: Weld neck flanges are often manufactured from materials that are highly resistant to corrosion (e.g., stainless steel, alloy steels, or specialized coatings). This makes them ideal for use in harsh environments, including chemical plants, marine systems, and oil and gas pipelines.

High-Temperature and High-Pressure Resistance: They can withstand high operating temperatures and pressures without compromising structural integrity, making them suitable for critical applications in power plants, refineries, and other industries where extreme conditions are common.

Smooth Flow Path: The tapering design of the weld neck flange ensures that the pipe's stress and pressure are distributed evenly, reducing the risk of fatigue over time. This makes weld neck flanges ideal for high-stress applications where vibration, thermal expansion, or mechanical stress is a concern.

Eliminates Stress Concentration: Unlike other flanges that might have sharp corners or abrupt transitions, weld neck flanges eliminate stress concentration points, making the connection more durable under fluctuating loads and conditions.

Precision Alignment: The design of the weld neck flange ensures that the pipe and the flange align precisely, which results in a more accurate and stronger weld. This reduces the chance of alignment issues during installation and ensures a better overall seal.

Titanium, carbon steel, and stainless steel are commonly used materials for flanges, each with different characteristics suitable for different applications.

Firstly, titanium alloy flanges are known for their excellent strength-to-weight ratio. Titanium alloys are both lightweight and strong, making them especially suitable for applications requiring high strength and lightweight properties, such as aerospace and marine industries. Additionally, titanium alloys have outstanding corrosion resistance, especially in highly corrosive environments like seawater, acids, and chemicals, making them ideal for extreme conditions. Titanium also performs well at high temperatures, maintaining strength up to approximately 600°C, and has good fatigue resistance. However, due to the rarity of titanium and its complex manufacturing process, titanium alloy flanges tend to be expensive.

The LHTi Titanium flange is designed to withstand high temperatures and pressures, making it highly reliable for different applications. It is made of high-quality Titanium material that is resistant to corrosion and offers high strength. The surface treatment of the product includes polishing, sandblasting, anodizing, and more, making it durable and long-lasting.

The LHTi Titanium flange is suitable for different application scenarios, which include:

High Strength-to-Weight Ratio: Titanium is both lightweight and strong, making it useful for reducing the overall weight of piping systems while maintaining strength.

Superior Corrosion Resistance: Titanium is especially effective in aggressive and high-temperature environments, such as those found in chemical, marine, and aerospace applications.

Durability and Longevity: Titanium flanges have a long service life due to their ability to resist corrosion, scaling, and wear, resulting in less frequent maintenance and replacement.

High-Temperature Resistance: Titanium can perform in a wide range of temperatures, including both cryogenic and high-temperature conditions, making it suitable for a variety of industrial applications.

Seamless and Strong Welds: The weld neck design ensures that the connection between the flange and pipe is strong and provides a smooth transition to avoid stress concentration.