What is carbon capture?

CCS is a technology that aims to reduce atmospheric carbon dioxide (CO₂) levels by capturing CO₂ from industrial processes and power generation, thereby preventing it from contributing to climate change. The captured CO₂ is then transported to safe storage sites and sequestered underground in geological formations to ensure it does not re-enter the atmosphere.

What is the difference between CCUS and CCS?

The difference between CCUS and CCS lies in the utilization aspect. While CCS focuses solely on the capture and storage of CO₂, CCUS involves the use of the captured CO₂ in various industries, turning it into a valuable commodity.

Carbon Capture, Utilization and Storage I CCUS Technology

Q: How is �����˿����� working on CCUS?

At �����˿�����, we are committed to advancing CCUS technologies through strategic partnerships and by leveraging our extensive experience in the power industry. Our capabilities extend beyond the core power plant infrastructure, where we can also offer integration of carbon capture equipment into existing and new facilities to ensure optimal performance. Our portfolio elements are broad and include compression and liquefaction solutions, control and automation solutions. In addition, our extensive experience as a service provider enables us to offer a comprehensive range of service solutions tailored to the specific needs of our customers.

Carbon Capture, Utilization, and Storage (CCUS) 

At ��˿��, we believe in the potential of Carbon Capture, Utilization, and Storage (CCUS). Advancing this technology is essential for a sustainable future. By partnering with customers, CCUS providers, and policymakers, we lead in decarbonizing the energy sector. Together, we are building a more sustainable world for future generations. Let’s turn ambition into action and create a cleaner, greener planet. 

To effectively combat climate change and reach net-zero emissions, a multitude of technologies are essential. CCUS will play a pivotal role in reducing CO₂ emissions by leveraging existing infrastructure. The underscores the necessity of CCUS, emphasizing the need to capture approximately 1 gigatonne of CO₂ annually by 2030 to align with international climate objectives, such as those set by the Paris Agreement. Integration design studies are important in refining CO₂ capture plants in terms of size, cost, and efficiency. Our equipment, including steam and gas compressors, facilitates CCUS deployment across the entire spectrum, encompassing capture, storage, and utilization.

The process of capturing CO₂ after combustion is notably energy-demanding, relying on electricity and low-pressure steam usually sourced from the power plant, which can diminish the plant's overall efficiency and power output. By optimizing steam turbine configurations and harnessing waste heat from CO₂ capture and compression, we can improve the power plant output, efficiency, and functionality of these plants.��

CCUS technologies can also capture��CO₂ directly with direct air capture (DAC) or from bioenergy processes (BECCS). These methods can remove��CO₂ from the atmosphere, helping to balance emissions that are difficult to eliminate.  Furthermore the synergistic approach of Direct Air Capture combined with carbon sequestration (DACCS) is acknowledged for its potential to generate negative emissions, representing a robust, enduring approach to Carbon Dioxide Removal.

In addition to our comprehensive approach to Carbon Capture, Utilization, and Storage (CCUS), we are also focusing on the system design aspects, including liquefication and drying. These processes are crucial for the efficient handling and storage of captured CO₂. Liquefication allows for the��CO₂ to be transported more easily and stored in a more compact form, while drying ensures that the��CO₂ is free from moisture, which can cause corrosion and other issues in storage and transportation systems.

The global energy landscape largely relies on fossil fuels, by 2035, DNV estimates ~30% of electricity will still come from fossil fuels . An abrupt switch to renewables is not yet feasible. CCUS-equipped gas-fired power generation complements renewable energy, ensuring availability and security when renewables are offline. We are leading in the development of CCUS technology, addressing climate change and supporting the transition to a low-carbon future. 

We have explored carbon management technologies for decades and continue to find ways to support the energy sector's transition with CCUS. Our extensive knowledge of energy systems allows us to work with industry partners to integrate carbon capture technology and create comprehensive CCUS solutions. 

Tailored CCUS solutions for a sustainable future 

Different technologies cater to various industries' needs, addressing their specific emission sources and regulatory environments. We�� collaborate with leading carbon capture providers to deliver efficient, reliable customized solutions.

Our strategic partnerships, combined with our extensive experience in energy technology, enable us to access cutting-edge technologies from leading suppliers. This allows us to concentrate on our core competency of integrating power plants with capture plants, thereby ensuring optimal efficiency and asset utilization.

CCUS technology landscape and infrastructure

CCUS is a key technological innovation aimed at reducing atmospheric carbon dioxide (CO₂) emissions. By capturing CO₂ from industrial processes, air and power and heat generation, CCUS prevents this greenhouse gas from impacting climate change. The captured CO₂ is then either repurposed in various industries or safely stored underground. CCUS is essential for lowering emissions in challenging sectors like steel and cement manufacturing and is a complement of sustainable low-carbon electricity and hydrogen production. As a method for atmospheric CO₂ removal, CCUS is integral to achieving net-zero emissions and ensuring long-term energy security.

Illustration of a CCUS process starting from the sources through collection and transportation up to utilization, or underground storage onshore and offshore.

CCUS offers significant potential for a sustainable future. Although high costs, infrastructure needs, and regulatory uncertainties pose challenges, they also drive innovation. Government support, such as tax credits and carbon pricing, can spur progress. Additionally, international collaboration and investment in R&D are essential for advancing CCUS technologies, enhancing their efficiency and cost-effectiveness. 

Embracing these opportunities will promote CCUS adoption, cut carbon emissions, and support a sustainable planet. 

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As a trusted partner, we help our customers select the most appropriate technologies for their specific needs. By partnering with leading carbon capture providers, we combine our energy technology and infrastructure expertise with their specialized knowledge to deliver efficient and reliable customized solutions.

Sustainable alternative fuels for gas turbines

A wide range of technologies and strategies are needed to tackle climate change and achieve net-zero emissions. CCUS stands out as a critical technology in this mission, providing a key solution to significantly reduce (CO₂) emissions while maintaining the use of critical energy infrastructure. CCUS involves capturing carbon dioxide from sources such as power plants and either reusing or storing them to prevent them from entering the atmosphere.

At ��˿��, we are committed to advancing CCUS technologies through strategic partnerships and by leveraging our extensive experience in the power industry. Our capabilities extend beyond the core power plant infrastructure, where we can also offer integration of carbon capture equipment into existing and new facilities to ensure optimal performance. Our portfolio elements are broad and include compression and liquefaction solutions, control and automation solutions. In addition, our extensive experience as a service provider enables us to offer a comprehensive range of service solutions tailored to the specific needs of our customers.��

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Carbon Capture, Utilization, and Storage (CCUS)

The climate imperative for Carbon Capture, Utilization and Storage

Partner with ��˿�� to decarbonize the energy sector

Tailored CCUS solutions for a sustainable future

CCUS technology landscape and infrastructure

What is Carbon Capture, Usage, and Storage (CCUS)?

How does CCUS technology work?

Transforming challenges into opportunities: The promising future of CCUS

Sustainable alternative fuels for gas turbines

Are you interested in our product portfolio?

Gas turbines

Combined cycle power plants (CCPPs)

Compressor solutions and services

Steam turbines

Get answers: FAQs on carbon capture, utilization and storage

Get in touch with us

�����˿�����

Carbon Capture, Utilization, and Storage (CCUS)

The climate imperative for Carbon Capture, Utilization and Storage

Partner with �����˿����� to decarbonize the energy sector

Tailored CCUS solutions for a sustainable future

CCUS technology landscape and infrastructure

What is Carbon Capture, Usage, and Storage (CCUS)?

How does CCUS technology work?

Transforming challenges into opportunities: The promising future of CCUS

Sustainable alternative fuels for gas turbines

Are you interested in our product portfolio?

Gas turbines

Combined cycle power plants (CCPPs)

Compressor solutions and services

Steam turbines

What is carbon capture?

Why is carbon capture, utilization and storage (CCUS) important?

What is the difference between CCUS and CCS?

How is �����˿����� working on CCUS?

Get in touch with us

��˿��

Carbon Capture, Utilization, and Storage (CCUS) 

Partner with ��˿�� to decarbonize the energy sector

Tailored CCUS solutions for a sustainable future 