Reducing the Carbon Footprint of Cement Production

Materials Engineering UBC

12 Aug 202208:40

Summary

TLDRSimon, a mechanical engineer at Calexor, discusses the company's involvement in Project Lilac, aimed at reducing CO2 emissions from the cement and lime industries, which contribute 7% of global CO2 emissions. He explains how Calexor's innovative technology can separate CO2 from the cement production process, making it possible to capture and repurpose or sequester the emissions. While the initial project scaled successfully, Lilac 2 faces challenges such as scaling up, adapting to various fuels, and integrating into a full cement plant. Simon emphasizes the importance of material science, team motivation, and his personal commitment to combating climate change through innovative technology.

Takeaways

😀 Simon is a mechanical engineer at Calexor, working on the Lilac Project aimed at reducing CO2 emissions in the cement and lime industries.
🌍 Cement and lime industries are responsible for about 7% of global CO2 emissions, which will increase as other industries decarbonize.
🔬 The Lilac Project targets CO2 emissions from the calcination process, a chemical reaction that releases CO2 when limestone is converted into lime.
🔥 The main challenge in cement production is separating CO2 from combustion gases during the calcination phase in the rotary kiln.
💨 The Lilac technology uses a reactor wall to separate CO2 from combustion gases, allowing for pure CO2 capture.
🌱 Captured CO2 can be used in agriculture, food production, or sequestered underground or in ocean aquifers.
⚙️ Scaling up the Lilac technology is a key challenge, as the small-scale version of Lilac 1 only handles a fraction of the total cement plant throughput.
⛽ Lilac 2 must accommodate a wider range of fuels used in the cement industry, including waste and biomass fuels, in addition to natural gas.
🏭 Integrating Lilac 2 technology into a full-scale cement plant presents new challenges due to tighter integration requirements.
🔬 Material science is crucial in addressing challenges related to fuel types and mechanical stresses in the reactor vessel.
💡 Simon emphasizes the importance of passionate and motivated individuals in the Lilac team, who are dedicated to overcoming the project's challenges.

Q & A

What is the main environmental problem that the Lilac project aims to address?
-The Lilac project seeks to reduce CO2 emissions from the cement and lime industries, which are responsible for about 7% of global CO2 emissions.
Why do cement and lime industries generate so much CO2, even with renewable energy sources?
-The high CO2 emissions in cement and lime production are due to the calcination process, where limestone (calcium carbonate) is converted into lime (calcium oxide), releasing CO2 as a byproduct. This is a chemical process that cannot be avoided, regardless of the energy source.
How does the cement production process contribute to CO2 emissions?
-Cement production involves three stages: drying and preheating, calcination (where CO2 is released), and clinker production. CO2 is emitted during the calcination phase when limestone is heated and undergoes a chemical transformation.
What is the key innovation introduced by the Lilac project in cement production?
-The Lilac project introduces a method to separate CO2 from combustion gases during the calcination process. This is achieved by using a reactor with a wall that divides the combustion process from the calcination reaction, enabling the capture of pure CO2.
What are the main challenges that the Lilac project faces in its scale-up phase?
-The three main challenges for the Lilac project in scaling up are: increasing the scale of the technology, adapting the technology to handle a wider variety of fuels used in the cement industry, and overcoming new integration challenges as the system becomes more tightly integrated into cement plant operations.
What fuels does the Lilac 2 technology need to accommodate, and why is this important?
-Lilac 2 needs to accommodate solid fuels, refuse-derived fuels, and biomass, in addition to natural gas. This is important because these are the fuels currently used by the cement industry, and the technology must be flexible enough to handle these diverse fuel sources for it to be effective at a commercial scale.
How does material science play a critical role in the Lilac project?
-Material science is vital to the Lilac project because it helps address challenges such as the extreme temperatures, mechanical stresses, and potential corrosion within the reactor vessel. The choice of materials directly impacts the success of the project, especially in terms of durability and efficiency.
Why is the Lilac 2 project seen as a demonstration for future cement plants?
-Lilac 2 is considered a demonstration project because it will integrate the CO2 separation technology into a full-scale cement plant, showcasing how the technology can work within existing plant operations and how it can be scaled for widespread implementation in the future.
What motivates Simon personally to work on the Lilac project?
-Simon is personally motivated by his commitment to combating climate change. He believes that the Lilac project has the potential to make a significant difference by reducing CO2 emissions from the cement industry, which is a major contributor to global emissions.
How does the team’s motivation influence the success of the Lilac project?
-The success of the Lilac project depends on the team's passion and intrinsic motivation. While skills and experience are necessary, it is the team's dedication and drive to achieve the project's goals that ultimately makes the difference in overcoming the challenges they face.