A Philippe Mege, Digital Services Factory Manager, Axens, Philippe.MEGE@axens.net Proposing a client upgrade a refinery plant from a conven - tional market to new products is generally based on con- sumer preferences, market trend analyses, and regulatory changes. AI can use machine learning algorithms to analyse historical data and make predictions about future market trends. It can also help by running different market scenar - ios to assess potential risks and associated impacts while developing a new product. NLP can also be used to extract valuable information from unstructured data sources to get a better understanding of the market and, therefore, stay ahead of the trends. A Ujjal Mukherjee, Chief Technology Officer, Lummus Technology AI, an integral part of a digital strategy, can be used effec - tively in retrofitting downstream units. We have a joint venture with TCG Digital, called Lummus Digital, which AI-driven digital solutions can be adjusted within equipment, product specification, and utility constraints to minimise energy and CO₂ emissions leverages AI-based platforms such as tcgmcube. We couple this with rigorous first principle-based process technology tools to take available data, quickly create digital twins, and develop unique hybrid solutions. These AI-driven digital solutions can be adjusted within equipment, product speci - fication, and utility constraints to minimise energy and CO₂ emissions while maximising production of the most valu- able products. These techniques are applicable to optimis - ing existing operations, designing new plants, or evaluating potential retrofit options. Once the products have been maximised within existing constraints, new solutions are developed with retrofits. This can include the change-out of catalyst systems, the addi- tion of new equipment, and sometimes entire upstream or downstream process technology. All of these impact the overall product slate while remaining within the turndown constraints of the base complex. Examples of such strategies include: •The introduction of biofeedstocks and waste plastic- derived pyrolysis oils to existing refineries or petrochemical complexes. • The elimination of gasoline production while maximising jet and diesel production, high-sulphur fuel oil production, and high-sulphur coke production. • Increasing chemicals production from 10-30% and sometimes 50% production of needle coke and anode coke from an existing coker, which is a dramatic shift in crude slates and more.
An increase in ethylene and propylene production can be reached by applying simple strategies to existing technolo- gies in the industry. For instance, increasing the severity in FCC units and/or using specific catalyst technologies and additives like ZSM-5 zeolite with high selectivity to olefins provides the product flexibility required by market demand. Even investment in additional and new technologies can be evaluated to maximise olefins production, like the integration of FlexEne technology, which is an innovative combination of two well-proven technologies – FCC and oligomerisation – to expand the capabilities of the FCC process to maximise olefins production, especially propylene. This flexibility is achieved by selective oligomerisation of light FCC alkenes (olefins) for recycle cracking in the FCC unit. Another important technology to be considered is High Severity Fluid Catalytic Cracking (HS-FCC), an excel - lent prospect for olefins maximisation. It is an evolution of the well-known FCC process to reach a considerably higher level of light olefins production, in particular propylene. This technology is, therefore, bridging the gap between the refining and petrochemicals industries. Q What role does artificial intelligence (AI) play in revamping downstream facilities that are scaling back on conventional fuels production while upgrading to capture value from new products? A Bradley Ford, Global Process Optimisation Solution Leader – Technology, KBC (A Yokogawa Company) The growing scarcity of skilled labour is impacting the per- formance of facilities worldwide. In fact, a study by Deloitte and The Manufacturing Institute reports that the manufac - turing skills gap in the US alone could result in 2.1 million unfilled jobs by 2030, resulting in a projected cost total - ling $1 trillion. As the industry pushes for optimisation, the infrastructure’s increasing complexity poses a challenge. KBC is observing the emergence of various types of AI technologies that are starting to address these challenges. For example, process simulation technologies are preva- lent at nearly all global assets, operating as process digital twins or online real-time optimisers. However, simulation models that reflect reality still require calibration from engi - neers. KBC now sees AI handling this critical task to: u Monitor the asset and models v Identify when calibration is lost w Automatically recalibrate it. The critical impact is allowing the available finite human resources to focus on higher-value tasks. Looking into the next steps, generative AI’s capabilities are potentially game-changing in capturing organisational knowledge that is dispersed across silos, contextualising that knowledge, and allowing junior staff to use it for idea generation. Careful oversight is needed to prevent genera- tive AI systems from ‘hallucinating’ or producing theoretical outputs that conflict with the data on which the algorithm has been trained. Hence, training programmes are required to educate staff on how to leverage generative AI to cre - ate ideas for improvement, which still requires peer reviews before implementation.
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PTQ Q2 2024
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