Benefits of Ashirwad Group Carbon Capturing Technology in the Cement Industry Significant Reduction of CO2 Emissions: The use of CCUS technology can capture up to 90-95% of CO2 emissions from cement plants, significantly reducing the industry's contribution to global greenhouse gas emissions.
Opportunities for Utilization of Captured CO2: The captured CO2 can be used for various applications, such as the production of synthetic fuels, chemicals, or as an input for algae growth. This not only helps to offset the costs of capture but also opens up new revenue streams for cement producers.
Enhanced Energy Efficiency: Some CCUS technologies, such as oxy-fuel combustion, can result in a more energy-efficient cement production process, contributing to further emissions reductions.
Enhanced Oil Recovery: One of the most prominent applications of Carbon Capturing in the oil and gas industry is Enhanced Oil Recovery (EOR). In this process, the captured CO2 is injected into mature oil fields to increase their productivity. The injection of CO2 reduces the viscosity of oil's and increases the flow rate, thus improving the recovery of oil from these fields. The CO2 stays sequestered in the oil reservoir after extraction. The use of anthropogenic CO2 for EOR, known as CO2-EOR, can create a market for captured CO2 while aiding in CO2 storage.
Natural Gas Processing: In natural gas processing plants, CO2 is often removed to meet the quality specifications of the marketed natural gas. This captured CO2 can be stored or utilized. converting a waste stream into a resource.
Refineries: Oil refineries, where crude oil is processed into various products, including gasoline, diesel, and jet fuels, are a significant source of CO2 emissions. CCUS can be used to capture and store or use these emissions, contributing to decarbonizing the refinery sector.
Ashirwad Carbonics Carbon Capture Technology in the Alcoholic Beverage industry primarily relates to the management and utilization of CO2 produced during the fermentation process. In the production of beer, wine, spirits, and other alcoholic beverages, yeast ferments sugars to produce alcohol and CO2. The carbon capture, utilization, and storage in this context involve capturing the emitted CO2 and repurposing it for other applications or storing it.
During fermentation, CO2 is emitted which can be captured through gas scrubbers or fermentation caps that channel the gas into storage or treatment units. The captured CO2 can be used in various applications, such as carbonation in soft drinks and beers, chilling and freezing, pH control, or inerting where CO2 is used to displace oxygen to prevent the degradation of a product. Another innovative application is using CO2 to grow algae that can be used as feedstock for biofuels or in wastewater treatment.
Innovative start-ups are also emerging in the Distilleries industry, utilizing captured CO2 for creating value-added products. For example, some companies are transforming CO2 into a key ingredient for making beverages or even creating diamonds from beer-based CO2 emissions.
Reduction in CO2 Emissions: The most evident benefit is a decrease in carbon emissions. The process of fermentation produces a significant amount of CO2, which if released into the atmosphere contributes to global warming. By capturing and storing or utilizing this CO2, breweries, wineries, and distilleries can reduce their carbon footprint.
Cost Savings and Revenue Generation: Captured CO2 can be repurposed for in-house use such as carbonation in beverages, saving costs on purchasing CO2. In addition, businesses can also sell excess CO2 to other industries, providing an additional revenue stream.
Energy Efficiency: Some businesses are exploring ways to use the captured CO2 for in-house energy generation, enhancing the overall energy efficiency of the operations.
Sustainable Branding: Implementing CCUS can be a key part of a company's sustainability efforts, appealing to eco-conscious consumers and potentially boosting brand image and market share.
The drive towards a sustainable and low-carbon future is steering industries towards innovative solutions. At the forefront of these strategies is Carbon Capture technology, which is gaining prominence in sectors like steel production and power generation.
Steel production is a major contributor to global CO2 emissions, responsible for approximately 7-9% of the total. With CCUS, there's an opportunity to substantially reduce this figure.
Blast Furnace Gas (BFG) Capture: A by-product of ironmaking, BFG contains a modest amount of CO2. Capturing this CO2 post-combustion, often through amine scrubbing, can help in addressing emissions, though it's a fraction of the total emissions from steelmaking.
Direct Reduced Iron (DRI) Process: This method proposes the use of hydrogen instead of coal or coke, facilitating a more concentrated CO2 emission that's easier to capture. The approach's effectiveness enhances when using hydrogen from renewable sources or capturing CO2 from hydrogen production
Calcination Process: Here, the CO2 released during lime production for steelmaking is of high purity and apt for capture and storage. Benefits in the Steel & Power Sector Carbon Capturing Technology
Decarbonization: A potential massive reduction in greenhouse gas emissions.
Energy Efficiency: Combining CCUS with technologies like hydrogen-based reduction can improve energy efficiency in steelmaking.
Cost Competitiveness: With evolving carbon pricing strategies, CCUS may drive cost benefits. especially in regions with strict emission norms.
