Technology
Switching to AFR using emerging & efficient technology
Published
6 years agoon
By
adminKHD Humboldt Wedag has state-of-the-art solutions for wide range of fuels and the same are being updated from time to time as per the demands of industry.
KHD Humboldt Wedag has vast experience in the field of providing latest state-of-the-art technologies and keeping-up the solutions ahead of the market requirement. The consistent market share for last 160 years is the benchmark that we have set-in and this legacy is continued with much more thrust in last 10 years. Coming to Alternative Fuels and Raw material (AFR) applications, we have diversified solutions depending up on the type of alternative fuel the end Customer wants to use. Snapshot of the product portfolio is summarised below:
PYRO-JET? AFR Kiln Burner: KHD has specially designed PYRO-JET? AFR kiln burner for maximum utilisation of alternative fuels. The unique features of this burner enables perfect flame shaping and mixing of fuels with oxygen from primary air and secondary air, faster AFR burn-out in the entrained phase, stable ignition and maintaining hot sintering zone due to better flame characteristics. For higher alternative fuel substituiton rates, the specially designed AFR retractable swirl nozzle is also configured in the system to make surte that fracturing, mixing of the AF flow achieved shortly before entering the kiln with appropriate spraying angle and improving the mixture within the flame core and with oxygen.
Alternative fuels such as plastic, paper foil, rice husk, RDF, saw dust, wood ships etc. with acceptable feed size can be fired in the kiln with this burner. Also, liquid alternative fuels such as solvent, pharmaceutical waste, etc. can be used in this burner with additional guide tube and associated valve train system.
PYROCLON? Calciner: Over the years, KHD has continuously improved the calciner systems to accommodate firing options to use wide range of alternative fuels. The KHD trade mark tubular calciners are perfect choice for firing coarse solid AFR, due to well balanced velocity and retention time inside the calciner. Patented PYROTOP?, part of the calciner takes care of mixing of fuel with gas & meal and also increases the retention time.
PYROCLON? R Calciner: Suitable for solid fuels with 2D size of <40 mm which can be lifted in the gas and easy to ignite.
PYROCLON? R Extended Calciner: Suitable for solid fuels with 2D size of <50 mm which can be lifted in the gas and easy to ignite.
PYROCLON? R Calciner + Combustion Chamber: Suitable for solid fuels with 2D size of <100 mm which are coarse and difficult to ignite. High calciner volume and additional residence time will be achieved with Combustion chamber. Start of combustion in pure tertiary air, open flame and center of combustion chamber is nearly kept free from meal leads to faster ignition. Additional mixing will be achieved at transition point of combustion chamber to calciner tube.
What are the advantages of this equipment and where they are installed?
In greenfield cement plants, the solutions discussed above can be integrated in the system design with minimal Capex to achieve maximum benefits. Also, in existing plants, most of these solutions can be introduced looking in to the layout feasibility. Solutions such as Burner, calciner, etc. are anyway required for clinker manufacturing process. Adopting them for suitable AFR usage can lead to advantages in terms of higher AFR substitution. The process advantages of these solutions are already discussed above.
We have AFR feeding and dosing installation references with renowned cement houses like UltraTech, Lafarge (now Nuvoco), Jaypee Cement (now UltraTech), J K Cement, etc.
What are the changes that have to be made in the process for installing these equipment?
In existing systems suitable adoptions in layout to be accounted for and in some cases tailor-made solutions to be exercised due to compact layouts. Further, looking in to the chemical composition, physical properties such as moisture etc. of fuels and its heat value, one has to review the capacity of Preheater fan. More often than not, the exhaust gas volume tend to increase with AFR usage at base clinker production rate.
It is necessary to have certain design margin for trouble free operation. Further, with respect to the chemical composition and circulating elements viz. Cl and S, necessary precautions to be incorporated in the system to avoid heavy build-ups, jamming issues by installing air blasters, compressed air rings at appropriate locations and if necessary bypass arrangement of kiln gases to minimise the operational constraints. Also, raw mix to be reviewed and optimised with respect to type of AFR usage.
How do they impact operating and capital costs? What are the factors one has to look into while selection of AFR materials?
For any alternative fuel usage, a detailed study is mandatory before going ahead with the execution of project. Of course, the availability of alternative fuels is one of the main criterions to be taken in to consideration. The capital costs are one time investment and should be evaluated on case to case basis looking in to the technology, reliability, availability of the system.
The overall operating cost is combination of lot of factors such as impact of AFR on specific power consumption, specific fuel consumption due to increased moisture and excess air requirement. Further detailed analysis to be exercised on the critical chemical components, which will influence the clinkerisation process such as sulphur, chlorine etc. High amount of such components can lead to continuous operational disturbances with clogging, coating, etc. which in turn influences the production rate. Such parameters to be critically analysed during the project inception stage itself. The following factors has influence on operating costs which needs to be reviewed thoroughly.
Influence on energy balance thus specific heat consumption
- Increased waste gas volumes (higher fuel moisture, fuel chemical composition, higher excess air demand, more fuel to maintain hot sintering zone).
- Higher amount of primary air (transport air) and leakage air, decrease of recuperation air from clinker cooler.
- In case of bypass system losses due to bypass gas extraction.
Influence on plant operation stability thus production rate
- High demands on fuel dosing equipment, continuous fuel feed.
- Formation of build-ups in case of Cl- and S- rich alternative fuels in the area at kiln inlet, riser duct, bottom most cyclone etc. This requires more manual cleaning efforts or else Bypass System is necessary.
Influence on clinker quality and market demand
- "Raining" of unburnt fuel out of the kiln flame to the clinker bed => reduced burning conditions.
- Cooling down of the sintering zone.
- Possible enrichment of harmful elements in clinker, e.g. MgO, P2O5 (depending on Alternative Fuel ash composition).
- Adaption of raw mix, e.g. high Fe- content in Alternative Fuel.
Influence on emissions / fossil fuel availability
- Positive influence on avoiding NOx formation and / or NOx reduction.
- CO formation in case of inadequate calciner technology or unsuitable secondary fuels.
- Saving of primary fossil fuel.
What are the advanced technologies available for AFR? How receptive have Indian cement manufacturers to these innovations?
As already explained above, we have state-of-the-art solutions for wide range of fuels and the same are being updated from time to time as per the demands of industry. Looking in to the difficulties in preparing the alternative fuels to the required size to be fed in already known solutions such as kiln burner, Calciner, Combustion chamber etc., we have recently come up with more robust latest generation solution i.e, PYROROTOR, suitable for firing coarse alternative fuels. Two such installations are under execution stage Globally and after reviewing the results we would like to introduce the same in Indian market. We are sure that this latest technology will change the course of AFR utilisation process in cement industry.
Features of PYROROTOR?: PYROROTOR, unique combustion reactor for cement plant applications for the thermal treatment of alternative fuels and raw materials. Due to high temperature process and longer residence time it is suitable for nearly all types of alternative fuels. Tertiary air is used as combustion air in PYROROTOR. Mechanical fuel transport through the reactor provides sufficient residence time. PYROROTOR is generally located above rotary kiln, between tertiary air duct and kiln riser duct. Indian cement manufacturers have always welcomed such new innovations. The cement market in India is competitive and manufacturers always strive for achieving price advantage by implementing new technologies. Higher AFR substitution rates can reduce the overall fuel cost which is one of the major cost input factor in clinker/ cement manufacturing. Solutions like PYROROTOR should become instant hit due to its unique advantages of suitability for using wide range of alternative fuels with minimum processing which reduces the preparation cost significantly.
What are the challenges companies face in sourcing AFR materials and what are the strategies they follow?
The majority of cement plants in India are using alternative fuels as an alternative energy source to minimise the operating cost by substituting usage of expensive fossil fuels. This gives competitive edge in terms of reduced manufacturing cost of clinker/cement. Also, there are few cement groups who has taken alternative fuels usage as a corporate social responsibility to minimise waste. However, in future, alternative fuels usage in cement industry works on sustainable basis if there is reasonable advantage to manufacturers in terms of cost reduction. As of now, the main challenge lies in availability of waste alternative fuels of consistent quality throughout the year.
Depending upon their geological locations and availability, the plants which are closer to the waste generation locations like pharmaceutical waste, treated RDF municipal solid waste, plastics, agriculture waste etc., are using AFR. The negative fuel cost in comparison to fossil fuels is working in cement plants favor as of now as these wastes are available at negative cost or at very marginal cost. The per kcal cost of prepared alternative fuel inclusive of sourcing, transportation, preparation, feeding etc. is lower than fossil fuel specific rate which keeps the balance to use AFR in cement plants. Looking in to this derivative, plants are sourcing and using alternative fuels on case to case basis. The evergreen economics rule of demand vs supply vs price will prevail and such situation may arise in future as the case is now for flyash, petcoke, etc. However, there should be some strict legislation from Government with well-modulated incentives to increase total substitution rate.
At what level is AFR used in Indian cement plants when compared to global benchmarks, and how long the industry may take to reach that level of efficiency?
The AFR substitution rate in Indian cement industry is less than 5 per cent TSR, which is remarkably low when compared to the standards of Europe where the AFR substitution rate is more than 40 per cent. There is huge scope for improving the figures that we are clocking today. It needs continuous support from Government and associated bodies. A critically reviewed vision plan to be laid out involving all the stakeholders to target the TSR levels of developed nations. Actions by all stakeholders are critical for realisation of the vision to become reality. Government and industry must take collaborative action to create a favorable framework for accelerating and implementation of AFR usage in cement plants.
Government should create and enable level playing field for the AFR users by providing interim financial stimulus packages that compensate and provide an edge in pricing pressures. Also, Government should take initiatives to establish latest state-of-art waste treatment plants, crop waste processing units, etc. in collaboration with cement plants in that particular cluster to supply segregated and treated alternative fuels.
Putting latest and innovative technological change into action is another aspect to improve the AFR usage. All stakeholders should intensify collaborative action to increase the implementation of state-of-the-art technologies and share best operating practices. Governments and industry should ensure sustained funding and supportive risk-mitigating mechanisms to promote the development and demonstration of new technologies and processes that offer increase in AFR utilisation. Such measures will act as springboard to improve the AFR utilisation and TSR in Indian cement industry.
About the authors: Authored by: Ashok Kumar Dembla, Managing Director & President, Humboldt Wedag India Pvt Ltd
Co-authored by: Sita Ram Sharma, Head – Parts & Services, Humboldt Wedag India Pvt Ltd.
By integrating advanced technologies like IoT and AI, cement plants are transforming into highly efficient and interconnected systems. ICR explores how these innovations enable real-time monitoring and predictive maintenance, significantly reducing downtime and operational costs.
The cement industry, traditionally known for its reliance on heavy machinery and manual processes, is undergoing a significant digital transformation. This shift is driven by advancements in technology that promise to enhance efficiency, reduce costs, and improve overall production quality. Key trends include the adoption of the Internet of Things (IoT), which enables real-time monitoring and control of production processes through interconnected devices. Artificial Intelligence (AI) and Machine Learning (ML) are being utilised to optimise operations, predict maintenance needs, and minimise downtime by analysing vast amounts of data. Additionally, the integration of Big Data analytics allows for more informed decision-making by providing insights into production trends and potential areas for improvement.
“One of the key advantages of integrating data across our systems is the ability to have a more transparent, agile, and integrated supply and logistics chain. With the implementation of Oracle Logistics Management Solution, we have been able to overcome challenges related to consignment locations and truck movements, providing real-time visibility into our operations. This has also led to operational efficiency improvements and the ability to predict consignment delivery times, which we share with our customers, enhancing their experience” says Arun Shukla, President and Director, JK Lakshmi Cement.
According to BlueWeave Consultancy, during the forecast period between 2023 and 2029, the size of India cement market is projected to grow at a CAGR of 9.05 per cent reaching a value of US$ 49.24 billion by 2029. Major growth drivers for the India cement market include the growing need from construction and infrastructure sectors and rising governmental initiatives and investments in expansive infrastructure ventures encompassing highways, railways, airports, and public edifices.
Importance of Digitalisation
Digitalisation in cement manufacturing is crucial for several reasons:
- Enhanced efficiency: Digital tools streamline production processes, reducing waste and improving the precision of operations. This leads to higher output and better resource utilisation.
- Predictive maintenance: By leveraging AI and IoT, cement plants can predict equipment failures before they occur, minimising unplanned downtime and extending the lifespan of machinery.
- Energy optimisation: Digital technologies enable the monitoring and optimisation of energy consumption, leading to significant cost savings and a reduced carbon footprint.
This aligns with global sustainability goals and regulatory requirements.
Quality control: Advanced sensors and data analytics ensure consistent product quality by closely monitoring and adjusting the production parameters in real time.
Safety improvements: Automation and robotics reduce the need for human intervention in hazardous environments, enhancing worker safety and reducing the risk of accidents.
Competitive advantage: Companies that embrace digitalisation can respond more quickly to market changes, innovate faster, and provide better customer service, giving them a competitive edge in the industry.
Digital transformation is reshaping the cement industry by driving efficiency, enhancing product quality, and promoting sustainability. As the industry continues to evolve, the adoption of digital technologies will be essential for maintaining competitiveness and achieving long-term success.
Key technologies driving digitalisation
The digital transformation of the cement industry is powered by a suite of advanced technologies that enhance efficiency, improve product quality, and drive sustainability. Here are some of the key technologies making a significant impact:
IoT refers to a network of interconnected devices that communicate and exchange data in real time. In the cement industry, IoT applications are revolutionising operations by enabling real-time monitoring and control of production processes. Sensors embedded in equipment collect data on various parameters such as temperature, pressure, and vibration. This data is then transmitted to a central system where it is analysed to optimise performance. For instance, IoT-enabled predictive maintenance systems can detect anomalies and predict equipment failures before they occur, minimising downtime and reducing maintenance costs. Additionally, IoT helps in energy management by monitoring consumption patterns and identifying opportunities for energy savings.
AI and ML in process optimisation are pivotal in enhancing process optimisation in the cement industry. AI algorithms analyse vast amounts of data generated from production processes to identify patterns and insights that human operators might overlook. ML models continuously learn from this data, improving their accuracy and effectiveness over time. These technologies enable real-time adjustments to production parameters, ensuring optimal performance and product quality. For example, AI-driven systems can automatically adjust the
mix of raw materials to produce cement with consistent properties, reducing waste and improving efficiency. AI and ML also play a crucial role in predictive maintenance, forecasting potential issues based on historical data and preventing costly equipment failures.
Tushar Kulkarni, Head – Solutions, Innomotics India, says, “Adoption of artificial intelligence (AI) will significantly help cement plants in their efforts towards innovation, efficiency and sustainability goals through improved process optimisation and increased productivity.”
“The Innomotics Digi-Suite (AI-based) is positioned to support the cement industry in this endeavour. Built on microservices architecture, Digi-Suite offers flexible self-learning AI based solutions which can be customised or tailor-made in accordance with plant / customer requirements. It enables customers to implement their digitalisation strategies in a stepwise manner and scale it up to an entire plant or multiple plants. Through this platform, customers can monitor and manage processes centrally. This approach provides guidance for company-wide process standardisation, knowledge sharing and optimum utilisation of expert resources,” he adds.
Big Data analytics involves processing and analysing large volumes of data to extract meaningful insights. In the cement industry, Big Data analytics is used for predictive maintenance and strategic decision-making. By analysing data from various sources such as sensors, machinery logs, and production records, companies can predict equipment failures and schedule maintenance activities proactively. This approach minimises unplanned downtime and extends the lifespan of critical assets. Furthermore, Big Data analytics helps in optimising supply chain management, inventory control, and production planning by providing actionable insights into trends and patterns. Decision-makers can leverage these insights to make informed choices that enhance operational efficiency and competitiveness.
Arun Attri, Chief Information Officer, Wonder Cement, says, “The advantages of data integration are substantial. By leveraging integrated data,
we build a single source of truth, we can identify patterns, optimise processes, and implement strategic initiatives that drive overall business growth. This approach not only enhances operational efficiency but also strengthens our relationships with all stakeholders by providing a clear and consistent view of our operations.”
“By establishing a single source of truth, we ensure that all stakeholders, both internal and external, have access to consistent and accurate data. This unified data repository enhances visibility into our operations, improves decision-making, and enables comprehensive analyses. For internal stakeholders, such as our production, quality and maintenance teams, this means having reliable data to optimise processes and schedule maintenance effectively. For external stakeholders, including suppliers and customers, it ensures transparency and trust, as they can rely on the accuracy of the information provided,” he adds.
Cloud computing offers a scalable and flexible solution for data storage and access, playing a vital role in the digitalisation of the cement industry. By storing data in the cloud, companies can easily access and share information across different locations and departments. Cloud-based platforms facilitate real-time collaboration and data sharing, enabling seamless integration of various digital tools and systems. Additionally, cloud computing provides robust data security and backup solutions, ensuring that critical information is protected and can be recovered in case of data loss. The scalability of cloud services allows cement manufacturers to handle the increasing volume of data generated by IoT devices and other digital technologies, supporting their growth and innovation initiatives.
Digital twin technology
Digital twin technology involves creating a virtual replica of a physical asset, process, or system. This digital counterpart is continuously updated with real-time data from sensors and other sources, mirroring the physical entity’s performance, behaviour and condition. In the cement industry, digital twins
offer numerous benefits. They enable real-time monitoring and analysis, allowing operators to visualise and understand complex processes in detail. This enhanced visibility helps in optimising production, improving efficiency, and reducing downtime. Digital twins also facilitate predictive maintenance by simulating various scenarios and identifying potential issues before they occur, thereby extending the lifespan of equipment and minimising maintenance costs. Moreover, they support data-driven decision-making by providing comprehensive insights into operations, leading to better resource management and increased productivity.
Tarun Mishra, Founder and CEO, Covacsis, explains, “Different plant data reside within the walls of individual plants. Comparing micro economic performance across plants is impossible. Covacsis’ IPF is designed to aggregate multiple plant’s data at unified enterprise datalike (historian) which then further used for relative baselining and relative performance analysis across same and similar asset base or product or processes.”
“Data plays the most important role in any algorithm. Big data and fast data are only adding to the logistics performance of any algorithm and platform. Covacsis is a decade old and most mature platform in the world. Covacsis’ SaaS infrastructure is already handling more than 350 billion of cement process and operation data on a daily basis with a compounding daily growth rate of 1 per cent. This provides a significant advantage to Covacsis towards building algorithms and ensuring the value efficacy of these algorithms for the industry,” he elaborates.
The implementation of digital twins in cement plants involves several steps. First, detailed models of the plant’s equipment, processes, and systems are created using data from various sources such as sensors, historical records, and engineering specifications. These models are then integrated into a digital platform that continuously collects and analyses real-time data from the physical plant. For instance, a digital twin of a cement kiln can monitor temperature, pressure, and other critical parameters, allowing operators to optimise the combustion process and improve energy efficiency.
Similarly, digital twins of grinding mills can help in adjusting operational parameters to achieve optimal particle size distribution and improve cement quality. The integration of digital twins with other digital technologies such as IoT, AI and Big Data analytics enhances their capabilities, providing a comprehensive and dynamic view of the entire production process. As a result, cement plants can achieve significant improvements in operational efficiency, product quality and sustainability.
Automation in cement production
Automation plays a pivotal role in enhancing productivity within the cement industry by streamlining operations and reducing the reliance on manual labor. Automated systems and machinery can perform repetitive and complex tasks with higher precision and consistency than human workers. This leads to significant improvements in operational efficiency and throughput. For instance, automated material handling systems can manage the movement and storage of raw materials and finished products more effectively, minimising delays and reducing handling costs.
Automated process control systems enable real-time monitoring and adjustments of production parameters, ensuring optimal performance and reducing waste. Additionally, automation helps in maintaining consistent product quality by minimising human errors and variations in the manufacturing process. Overall, the integration of automation technologies results in faster production cycles, lower operational costs, and increased competitiveness in the market.
The introduction of automation in the cement industry has a profound impact on workforce skills and safety. As automation takes over routine and hazardous tasks, the demand for manual labour decreases, and the focus shifts to more technical and supervisory roles. Workers are required to develop new skills in operating and maintaining automated systems, as well as in data analysis and problem-solving. This shift necessitates continuous training and upskilling to ensure the workforce can effectively manage and leverage advanced technologies.
On the safety front, automation significantly enhances worker safety by reducing their exposure to dangerous environments and tasks. Automated systems can handle heavy lifting, high-temperature processes, and exposure to harmful dust and chemicals, thereby minimising the risk of accidents and occupational health issues. As a result, automation not only boosts productivity but also contributes to a safer and more skilled workforce, fostering a more sustainable and resilient industry.
Energy efficiency and sustainability
Digital tools are revolutionising the way energy consumption is monitored and optimised in the cement industry. Advanced sensors and IoT devices continuously collect data on energy usage across different stages of the manufacturing process. This real-time data is analysed using AI and machine learning algorithms to identify patterns, inefficiencies, and opportunities for energy savings. Energy management systems (EMS) integrate these digital tools to provide a comprehensive overview of energy consumption, allowing operators to make informed decisions to reduce energy waste. For instance, predictive analytics can forecast energy demands and optimise the operation of high-energy equipment, such as kilns and grinders, to align with periods of lower energy costs. Additionally, automated control systems can adjust operational parameters to maintain optimal energy efficiency, thereby reducing the overall energy footprint of the plant.
McKinsey & Company for the cement industry analyse that pursuing digitisation and sustainability levers are key to significantly boosting productivity and efficiency of a typical cement plant. The result is a margin gain of $4 to $9 per tonne of cement, which would shift a traditional plant to the top quartile of the cost curve for plants with similar technologies.
Digital technologies are also instrumental in driving sustainable practices within the cement industry. By providing precise control over production processes, digital tools help in minimising raw material wastage and reducing emissions. For example, advanced process control (APC) systems optimise the combustion process in kilns, leading to more efficient fuel use and lower carbon dioxide emissions. Digital twins, which create virtual replicas of physical assets, enable detailed simulations and scenario analyses, allowing companies to explore and implement more sustainable production methods. Furthermore, the integration of renewable energy sources,
such as solar and wind power, is facilitated by digital technologies that manage and balance energy loads effectively.
Digital platforms also support the implementation of circular economy practices, such as the use of alternative fuels and raw materials, by tracking and optimising their utilisation throughout the production cycle. Overall, digital technologies empower the cement industry to achieve significant advancements in energy efficiency and sustainability, contributing to environmental conservation and compliance with global sustainability standards.
Future of digitalisation
The cement industry is on the brink of a significant transformation driven by emerging technologies. Innovations such as artificial intelligence (AI), machine learning (ML), advanced robotics, and blockchain are poised to revolutionise various aspects of cement production and supply chain management. AI and ML will enable more sophisticated predictive maintenance and process optimisation, reducing downtime and increasing efficiency. Advanced robotics will automate more complex and hazardous tasks, further enhancing productivity and worker safety. Blockchain technology offers potential benefits in enhancing transparency and traceability in the supply chain, ensuring the integrity of product quality and compliance with environmental regulations. These emerging technologies will collectively contribute to a more efficient, reliable, and sustainable cement industry.
Smart cement plants represent the future of the industry, where digital technologies are fully integrated to create highly automated and interconnected production environments. In these plants, IoT devices, digital twins and AI-driven systems will work together seamlessly to monitor, control and optimise every aspect of the manufacturing process. Real-time data from sensors will feed into advanced analytics platforms, enabling instant adjustments to maintain optimal performance. Digital twins will allow operators to simulate and test changes in a virtual environment before implementing them in the physical plant, minimising risks and enhancing decision-making. Furthermore, smart cement plants will incorporate renewable energy sources and energy storage solutions, supported by intelligent energy management systems that ensure efficient and sustainable operations.
Over the next decade, the digital transformation of the cement industry is expected to accelerate, driven by continuous advancements in technology and increasing demands for sustainability. We can anticipate widespread adoption of AI and ML for real-time process optimisation and predictive maintenance, leading to significant reductions in operational costs and emissions. The use of digital twins will become standard practice, enabling more precise and flexible production planning and execution.
Enhanced connectivity and data sharing across the supply chain will improve efficiency, transparency, and collaboration among stakeholders. Additionally, the integration of renewable energy and advanced energy storage solutions will become more prevalent, supported by digital platforms that optimise energy usage and reduce environmental impact. As the industry embraces these digital innovations, we will see a new era of smart, sustainable, and highly efficient cement manufacturing, positioning it to meet the challenges and opportunities of the future.
Conclusion
The digital transformation of the cement industry is poised to revolutionise traditional manufacturing processes, driving significant advancements in efficiency, sustainability, and competitiveness. Emerging technologies such as IoT, AI, ML advanced robotics, and blockchain are not only optimising energy consumption and improving operational efficiency but are also paving the way for more sustainable practices. The evolution towards smart cement plants, where digital tools are fully integrated, is set to redefine production environments with enhanced automation, real-time monitoring and advanced analytics.
Over the next decade, we can expect these technologies to become standard practice, leading to substantial reductions in costs and emissions, improved supply chain transparency, and greater adoption of renewable energy sources. As the industry embraces digitalisation, it will be better equipped to meet future challenges and seize new opportunities, ultimately contributing to a more sustainable and resilient
global economy.
– Kanika Mathur
Concrete
Advantages of data integration are substantial
Published
4 months agoon
August 23, 2024By
RoshnaArun Attri, Chief Information Officer, Wonder Cement, discusses the digital transformation and advanced technologies used to enhance operational efficiency, sustainability and cybersecurity in their cement manufacturing processes.
How has the implementation of IT initiatives transformed your operations and processes in the cement industry?
We operate under the digital vision: To leverage digital to accelerate growth, build relationships and enhance consumer experience.
Our digital transformation initiatives have profoundly reshaped operations and processes at Wonder Cement. By integrating advanced technologies such as IoT, cloud computing and constructing a data lake house for data consolidation as a single source of truth, we have enabled seamless information flow between applications and developed real-time analytics. These advancements have streamlined our production processes, enhanced operational efficiency, and improved decision-making. Additionally, predictive analytics allows us to anticipate market trends and customer needs more accurately.
Can you discuss how your organisation is adopting Industry 4.0 technologies and the benefits you are experiencing?
Embracing Industry 4.0 technologies is truly transforming our operations and improving reliability. Here are the key benefits we are experiencing:
- Real-time monitoring: IoT devices provide real-time data on equipment performance, enabling predictive maintenance and reducing downtime.
- Process optimisation: AI and machine learning algorithms enhance process optimisation,
leading to increased efficiency and reduced operational costs. - Higher productivity: Improved monitoring and optimisation result in higher productivity and better product quality.
- Enhanced sustainability: Better resource utilisation contributes to enhanced sustainability.
What specific automation technologies have you implemented, and how have they improved efficiency and productivity in your cement plants?
Automation technologies have revolutionised efficiency and productivity at our cement plants. Automated quality control systems ensure consistent product quality by continuously monitoring and adjusting production parameters. Robotic process automation (RPA) in administrative functions like inventory management and order processing has drastically reduced manual errors and boosted operational efficiency. These advancements enable us to uphold high standards of precision and reliability, optimise resource utilisation and minimise wastage.
How are predictive analytics and maintenance technologies being utilised in your operations to minimise downtime and optimise maintenance schedules?
Predictive analytics and maintenance technologies are pivotal in minimising downtime and optimising maintenance schedules at Wonder Cement. By analysing historical data and real-time sensor inputs, we proactively predict and address potential equipment failures. This approach has drastically reduced unplanned downtime, enhanced equipment reliability, and extended machinery lifespan. Our maintenance teams use these insights to schedule activities during planned shutdowns, ensuring minimal production disruption. This proactive strategy has led to substantial cost savings and significantly boosted overall plant efficiency.
What are the challenges and advantages of integrating data across various systems in your cement manufacturing process?
Integrating data across various systems in our cement manufacturing process presents both challenges and advantages. One of the primary challenges is ensuring data consistency and accuracy across different platforms. To address this, we have implemented robust data integration and validation frameworks that facilitate seamless data flow and synchronisation.
The advantages of data integration are substantial. By leveraging integrated data, we build a single source of truth, we can identify patterns, optimise processes, and implement strategic initiatives that drive overall business growth. This approach not only enhances operational efficiency but also strengthens our relationships with all stakeholders by providing a clear and consistent view of our operations.
By establishing a single source of truth, we ensure that all stakeholders, both internal and external, have access to consistent and accurate data. This unified data repository enhances visibility into our operations, improves decision-making, and enables comprehensive analyses. For internal stakeholders, such as our production, quality and maintenance teams, this means having reliable data to optimise processes and schedule maintenance effectively. For external stakeholders, including suppliers and customers, it ensures transparency and trust, as they can rely on the accuracy of the information provided.
How is digitalisation contributing to sustainability efforts and reducing the environmental impact of your cement production?
IT initiatives play a pivotal role in supporting our sustainability efforts and reducing the environmental impact of cement production at Wonder Cement. One of the key contributions of IT is the optimisation of energy consumption. Through advanced energy management systems, we continuously monitor and analyse energy usage across our operations. This allows us to identify areas of inefficiency and implement measures to reduce energy consumption, such as adjusting process parameters and utilising energy-efficient equipment.
Additionally, IT enables us to track and manage emissions more effectively. By integrating emission monitoring systems with our IT infrastructure, we can continuously measure and analyse emission levels, ensuring compliance with environmental regulations and identifying opportunities for reduction. For instance, real-time data on CO2 emissions allows us to adjust our production processes to minimise the carbon footprint.
IT initiatives also facilitate the implementation of circular economy practices. Through sophisticated waste management systems, we can monitor and optimise the use of alternative fuels and raw materials, reducing our reliance on traditional resources and minimising waste generation.
With the increasing digitisation of operations, what steps are you taking to ensure cybersecurity and protect sensitive data?
With the increasing digitisation of operations, ensuring cybersecurity and protecting sensitive data is paramount at Wonder Cement. We have implemented advanced technologies such as artificial intelligence and machine learning (AI/ML) for threat detection and response, and Secure Access Service Edge (SASE) to provide secure and efficient network access. Additionally, our Security Operations Centre (SOC) continuously monitors our digital infrastructure, utilising AI/ML to identify and mitigate potential threats in real-time. Comprehensive cybersecurity measures, including firewalls, intrusion detection systems, and regular security audits, further safeguard our systems. We also conduct regular training sessions for our employees to raise awareness about cybersecurity best practices and potential threats. By prioritising cybersecurity, we ensure the confidentiality, integrity, and availability of our critical data and systems, staying ahead of emerging cyber threats.
What future IT trends do you foresee having the most significant impact on the cement industry, and how is your organisation preparing to embrace these trends?
Looking ahead, we foresee several IT trends that will significantly impact the cement industry. These include the further integration of AI and machine learning for advanced process optimisation, the adoption of blockchain technology for transparent and secure supply chain management, and the expansion of IoT applications for enhanced monitoring and control. Additionally, the use of drones for site inspections, computer vision for quality control, generative AI for innovative design solutions, and robotics and RPA for automating repetitive tasks will bring substantial benefits. At Wonder Cement, we are actively preparing to embrace these trends by investing in research and development, collaborating with technology partners, and continuously upgrading our IT infrastructure. Our proactive approach ensures that we remain at the forefront of technological advancements, driving innovation and maintaining our competitive edge.
– Kanika Mathur
At the World Cement Association’s annual conference the WCA Director, Emir Adiguzel addressed the global cement industry to outline the challenges and opportunities facing the global cement industry.
The conference held in Nanjing, had industry leaders, innovators and stakeholders in attendance to discuss the future of cement production and sustainability. The WCAA director emphasised on the cement industry’s stern commitment to sustainability; spoke about the global cement demand and market dynamics, projecting a period of stagnation from 2024-2030 with growth expected only in the Middle east, India and Africa; about the challenges and opportunities in carbon capture technology hat show promise but will need further development and substantial investment as well as about the strategic initiatives and collaboration within the industry in improving sustainability and operational performance.
Adiguzel concluded his address by highlighting the crucial point where the global cement industry stands by saying “Collaboration within the World Cement Association is essential for sharing knowledge and aligning on long-term objectives. Ensuring the industry’s resilience and adaptation to evolving market dynamics is crucial for the survival of independent cement producers”.