company news about The Flange's Role in Carbon Capture and the Green Economy

As the world rapidly transitions to a green economy, the humble metal flange is finding itself on the front lines of climate technology, playing an essential role in emerging systems like Carbon Capture, Utilization, and Storage (CCUS). These technologies are crucial for mitigating climate change, and their demanding operating conditions place new and specific challenges on flanges, pushing the boundaries of material science and design.

CCUS involves capturing carbon dioxide (CO2​) emissions from industrial sources (like power plants, steel mills, or cement factories), transporting the gas, and either using it for industrial processes or injecting it deep underground for long-term storage.

The Demands of Flanges in CCUS:

1. Corrosion by Wet $C{O}^2$:

   • When CO2​ is mixed with water, it forms carbonic acid, which is corrosive to many common grades of steel. For flanges in the capture and compression stages, where the CO2​ is often wet, materials must be selected to resist this carbonic acid corrosion. Higher grades of carbon steel with corrosion inhibitors or stainless steels are often considered.

2. High Pressure for Transport:

   • For efficient transport over long distances via pipeline, the captured CO2​ is compressed to a supercritical state, where it behaves as a dense fluid. This requires extremely high pressures, often exceeding 1000 psi, and sometimes reaching thousands of psi. Flanges must be rated to withstand these pressures, often necessitating a Class 600 or higher rating.

3. Low Temperatures for Liquefaction:

   • In some cases, CO2​ is transported as a cryogenic liquid. Flanges for this service must be made from materials that retain their toughness and are resistant to brittle fracture at very low temperatures (e.g., A350 LF2/LF3 or austenitic stainless steels).

4. Flange Integrity for Containment:

   • The primary goal of a CCUS system is to safely contain the CO2​. A leaking flange is a failure in this mission, leading to a loss of the captured carbon and compromising the entire process. Flanges and their gaskets must provide an exceptionally tight and long-lasting seal, especially given the smaller molecular size of CO2​ compared to liquids.

5. Material Compatibility with Impurities:

   • The captured CO2​ is often not pure; it may contain trace amounts of other gases (e.g., H2​S, NOx​, SO2​) that can be highly corrosive. The flanges must be designed to withstand this cocktail of aggressive chemicals.

Specialized Flange Solutions for CCUS:

• Weld Neck Flanges: Given the criticality and high pressure of the service, weld neck flanges are the preferred choice for their superior integrity.

• Ring Type Joint (RTJ) Flanges: For the most critical high-pressure sections, RTJ flanges with a metal-to-metal seal are used to ensure maximum containment and blow-out resistance.

• Corrosion-Resistant Materials: Flanges might be made from duplex stainless steel or even corrosion-resistant alloy steels for specific parts of the process.

• Rigorous Inspection: The entire system, including every flanged joint, undergoes meticulous inspection (e.g., NDE, hydrostatic/pneumatic testing) to ensure leak tightness before commissioning.

The role of metal flanges in CCUS is a powerful example of how a seemingly conventional component can be repurposed to meet the demands of a new and crucial technology. They are the silent, steadfast joints that enable the safe and secure transport and storage of carbon, making them an indispensable part of the engineering foundation of our sustainable future.