Who We Are
Cryo Recovery: Innovative Solutions for Gas and Chemical Recovery in Industrial Processes
Cryo Recovery is used for the recovery of gas or chemicals in production or refining processes. The Cryo Recovery process involves the use of a low-temperature cooling system, usually using liquid nitrogen or other cryogenic substances, to cool the gas or chemical mixture. Cooling causes the desired substances to condense, which are then separated and recovered from the mixture.
Cryo Recovery is used in various industries, including the petrochemical industry, for the recovery of chemicals or gases such as ethane, methane or propane. The technology is particularly useful when the substances to be recovered are present in very small quantities or in mixtures with other substances, making their recovery difficult with other methods.
Related Downloads
NGL/LPG Cryo Recovery
The recovery of NGL/LPG is typically accomplished through cryogenic processing, with minimum temperatures that can be as low as -80oC (NGLs) or -110oC (for high-efficiency C2 recovery).
Cryogenic processing requires proper gas dehydration, which is typically achieved using molecular sieves for lower temperatures.
NGL/LPG cryogenic recovery is a process used to recover natural gas liquids (NGLs) and liquefied petroleum gas (LPG) from natural gas streams.
The process involves cooling the natural gas stream to a temperature where the NGLs and LPG can be liquefied and separated from the natural gas. The liquefied NGLs and LPG are then separated from each other using distillation or other separation techniques.
This process can also be used to recover CO2 from the natural gas stream by separating it from other gases.
The resulting high-purity CO2 can be used for carbon credits or other applications.
NGL/LPG cryogenic recovery technology is widely used in the natural gas industry and can help to reduce greenhouse gas emissions by capturing and separating CO2 and other gases from natural gas streams.
NGL/LPG cryogenic recovery is a highly specialized process used to recover natural gas liquids (NGLs) and liquefied petroleum gas (LPG) from natural gas streams. The process involves several steps, including cooling the natural gas stream to a temperature where the NGLs and LPG can be liquefied and separated from the natural gas.
The liquefaction process typically involves the use of a cryogenic refrigeration system, which cools the natural gas stream to temperatures as low as -120°C (-184°F).
At these temperatures, the NGLs and LPG components of the natural gas stream condense into a liquid state and can be separated from the natural gas using various separation techniques.
The separated NGLs and LPG are then further processed using distillation or other separation techniques to remove impurities and obtain a final product with the desired composition and purity. The final product is then transported to storage tanks or directly to customers for use as fuel or other industrial applications.
NGL/LPG cryogenic recovery technology can also be used to recover CO2 from natural gas streams.
This involves separating the CO2 from the other gases in the natural gas stream, which can then be liquefied and stored for use in carbon capture and storage (CCS) or other applications.
The resulting high-purity CO2 can be used for carbon credits or other applications, such as enhanced oil recovery, where the CO2 is injected into oil wells to enhance oil recovery rates.
NGL/LPG cryogenic recovery technology is widely used in the natural gas industry and can help to reduce greenhouse gas emissions by capturing and separating CO2 and other gases from natural gas streams.
The technology is also highly energy-efficient, with the liquefaction process requiring significantly less energy than other gas separation technologies.
In summary, NGL/LPG cryogenic recovery is a highly specialized process used to recover natural gas liquids and liquefied petroleum gas from natural gas streams.
The process involves cooling the natural gas stream to a temperature where the NGLs and LPG can be liquefied and separated from the natural gas.
The resulting high-purity CO2 can also be used for carbon credits or other applications, making this technology an important tool for reducing greenhouse gas emissions in the natural gas industry.
Spanish 
English 
French