Enviromentally Friendly Carbon Monoxide Gas Recovery Gas Liquid CO Generator Equipment
Wobo is dedicated to the engineering design, equipment manufacturing, and provision of complete sets of experimental-grade gas and liquid carbon monoxide solutions. Our proprietary technologies, such as low-temperature distillation, multi-stage distillation,and multi-stage liquefaction, enable our equipment to be suitable for various geographical and climatic conditions. Through optimization and improvement of the process flow and key equipment, our system offers advantages such as low investment, small footprint, and thorough purification.
With over 100 sets of different raw material gas carbon monoxide units, we have extensive experience in designing, manufacturing, and installing standardized carbon monoxide equipment. Our products are exported to countries and regions including the United States, Peru, Ukraine, Russia, India, Cameroon, and Algeria. The largest single carbon monoxide unit we have developed has reached a capacity of 500,000 tons per annum.
Our equipment is applicable for capturing and separating carbon monoxide from waste gases for reuse or safe disposal. It finds applications in various industries, including petrochemical refineries, steel mills, syngas production plants, and waste-to-energy facilities.
1. Cryogenic Carbon Monoxide Separation Process:
The cryogenic carbon monoxide separation process involves the use of low temperatures to condense and separate carbon monoxide from gas mixtures. At extremely low temperatures, carbon monoxide can be liquefied while other gases remain in gaseous form. This process relies on the differences in boiling points of the components in the gas mixture. The carbon monoxide gas is cooled and compressed to the point where it liquefies, allowing for its separation from other gases. The separated carbon monoxide can then be collected and further processed or utilized.
2. Membrane Separation Process of Carbon Monoxide:
The membrane separation process utilizes selective membranes to separate carbon monoxide from gas mixtures. These membranes have specific permeability properties that allow carbon monoxide molecules to pass through while blocking other gases. The feed gas mixture is passed over the membrane, and carbon monoxide selectively permeates through the membrane, leaving behind other gases. The separated carbon monoxide can be collected and utilized, while the remaining gas mixture is depleted in carbon monoxide. This process is suitable for applications where high-purity carbon monoxide is required.
3. Solution Absorption and Separation Process of Carbon Monoxide:
The solution absorption and separation process involves using a liquid solvent to selectively absorb carbon monoxide from gas streams. A suitable solvent, such as an amine-based solution, is contacted with the gas mixture containing carbon monoxide. The carbon monoxide preferentially reacts with the solvent, forming a soluble complex, while other gases are not significantly absorbed. The solution is then separated from the gas mixture, and the carbon monoxide is desorbed from the solvent using temperature or pressure swing methods. This allows for the recovery and purification of carbon monoxide from gas streams.
4. PSA Process for Separating Carbon Monoxide:
The Pressure Swing Adsorption (PSA) process is commonly used for separating carbon monoxide from gas mixtures. It involves the use of adsorbents, such as zeolites or activated carbon, which have a high affinity for carbon monoxide. The gas mixture is pressurized and passed through a bed of adsorbent material. Carbon monoxide molecules are selectively adsorbed onto the surface of the adsorbent, while other gases are not significantly adsorbed. The adsorbent bed is then depressurized, allowing for the desorption and regeneration of the adsorbent. This cyclic process enables the separation and collection of carbon monoxide with high purity.
Product name |
CO Carbon monoxide separator |
Product Gas Scale |
100~40000 Nm3/h |
Product Purity |
98.5%~99.99% |
Carbon Monoxide Yield |
At a purity of 98.5%, the yield ranges from 75% to 95% |
Plant Consumption |
With the same product yield and purity, energy consumption is more than 30% lower compared to other domestic pressure swing adsorption processes, and raw material gas usage is reduced by over 50%. |
Parameters may vary with different carbon dioxide gas raw materials |
We can customize it according to your requirements. |
1. Membrane Separation Equipment for Carbon Monoxide:
In the context of membrane separation for carbon monoxide, a mixed gas stream is introduced into the membrane separation equipment. The equipment consists of semi-permeable membrane units that employ specific separation characteristics to segregate carbon monoxide from other gases. Through a controlled separation process, these membranes allow carbon monoxide to permeate while retaining other components. The resulting carbon monoxide stream is collected and may undergo additional purification steps to meet the required purity level. Vigilant control and monitoring are crucial to maintain stable operation and the desired separation outcome throughout the membrane separation process.
2.PSA Carbon Monoxide Separation Equipment:
In the process of Pressure Swing Adsorption (PSA) for carbon monoxide purification, a mixture of gases containing carbon monoxide is sourced and compressed before entering the PSA equipment. Within the equipment, specialized adsorbent beds selectively adsorb carbon monoxide while allowing other gas components to pass through. As the beds become saturated over time, a reduction in pressure facilitates desorption, releasing a concentrated stream of carbon monoxide. This enriched carbon monoxide stream is then collected, separated, and further refined to achieve the desired purity. Multiple adsorbent beds operate cyclically with an automated control system to ensure effective carbon monoxide purification.
1. The technology is advanced and well-established, with a straightforward process flow.
2. Our independently developed carbon monoxide-specific adsorbents have a high separation coefficient and achieve excellent purification results.
3. The carbon monoxide-specific adsorbents undergo pre-reduction before leaving the factory, allowing for direct on-site loading and usage without the need for extended on-site reduction cycles. This approach also avoids the issues of high gas consumption during on-site reduction and the emission of chlorine-containing gases during the reduction process.
4. Our internally developed patented pressure swing adsorption technology ensures operational flexibility, secure and stable operation of the equipment, and a compact footprint.
5. The carbon monoxide yield is high, and the energy consumption and operational costs for carbon monoxide purification are minimal.
Chemical Industry |
Laboratory and Research |
Gas Purification |
Energy Storage and Conversion |
Metal Production |
Specialty Gas Production |
Carbon Monoxide Gas Cylinders |
Carbon Monoxide Liquid Storage Tanks |
Catalytic Converters |