Carbon Dioxide Gas Liquid Generator Plant
Enviromentally Friendly CCUS Carbon Capture CO2 Utilization and Storage System:
Small Footprint CCUS Carbon Capture Utilization and Storage Plant From Air
CCUS (Carbon Capture, Utilization, and Storage) technology is crucial for achieving carbon neutrality. It involves capturing, utilizing, and storing carbon dioxide emissions from large-scale sources using chemical and physical methods. This technology effectively mitigates greenhouse gas emissions and is considered a vital approach for significantly reducing emissions in the future.
WOBO GROUP is actively involved in the development and application of carbon capture and utilization technologies, thereby contributing to the advancement of CCUS technology.
Product Description
CCUS refers to a suite of technologies that involves the capture of CO2 from large point sources, including power generation or industrial facilities that use either fossil fuels or biomass for fuel. The CO2 can also be captured directly from the atmosphere. If not being used on-site, the captured CO2 is compressed and transported by pipeline, ship, rail or truck to be used in a range of applications, or injected into deep geological formations (including depleted oil and gas reservoirs or saline formations) which trap the CO2 for permanent storage. The extent to which CO2 emissions are reduced in net terms depends on how much of the CO2 is captured from the point source and whether and how the CO2 is used.
What CCUS technologies are available? |
* Mobile Carbon Capture technologies capture CO2 from mobile sources and store the gas on board, ready for sequestration or utilization |
* Direct Air Capture (DAC) processes capture CO2 directly from the atmosphere (rather than at source), to be sequestered or utilized |
* Bio Energy Carbon Capture and Storage technologies extract and store CO2 from biomass, itself a renewable energy source |
Process Flow Diagram
Carbon Dioxide Capture Technology
PSA METHOD
PSA CO2 purification unit utilizes molecular sieves as adsorbents and employs the principle of pressure swing adsorption to separate and extract CO2 from gases.
Applicable Scope:
Flue gas with CO2 content ranging from 40% to 80%
Application Scenarios:
Alcohol Plants, Natural Gas Decarbonization, etc.
CRYOGENIC LIQUEFACTION SEPARATION METHOD
CO2 separation involves liquefying gases at low temperatures, followed by separating them based on differences in boiling points
between CO2 and other gases.
Applicable Scope:
High CO2 content flue gas (CO2 content ≥80%)
Application Scenarios:
Refineries, Coal Chemical Plants, etc.
CHEMICAL ABSORPTION METHOD
Flue gas is scrubbed and then absorbed in a tower to capture CO2. High-temperature regeneration releases CO2 gas, which is
compressed, dried, and cooled to liquid form.
Applicable Scope:
Flue gas with low CO2 content
Application Scenarios:
Power Plants, Combustion-based Flue Gas.
SEPARATION MEMBRANE
Membrane CO2 separation units utilize advanced hollow fiber membrane separation technology to purify CO2 from gases.
Applicable Scope:
Flue gas with CO2 content ranging from 40% to 80%
Application Scenarios:
Alcohol Plants, Natural Gas Decarbonization, etc.
Product Advantages
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