Real-Time Lime-Storage Tracking Model in Steel-Making Plan
Vipul Kumar Tiwari1, Kumar Gaurav2, Umesh Kumar Singh3, Jose Martin Korath4, Manish Kumar Singh5
1Vipul Kumar Tiwari*, Technologist, Automation Division, Tata Steel, Jamshedpur, 831001, India.
2Kumar Gaurav, Technologist, Automation Division, Tata Steel, Jamshedpur, 831001, India.
3Umesh Kumar Singh, Principal Technologist, Automation Division, Tata Steel, Jamshedpur, 831001, India.
5Manish Kumar Singh, Chief (One IT), Automation Division, Tata Steel, Jamshedpur, 831001, India.
Manuscript received on December 28, 2021. | Revised Manuscript received on January 03, 2021. | Manuscript published on February 28, 2021. | PP: 34-40 | Volume-10 Issue-3, February 2021. | Retrieval Number: 100.1/ijeat.C21770210321 | DOI: 10.35940/ijeat.C2177.0210321
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© The Authors. Blue Eyes Intelligence Engineering and Sciences Publication (BEIESP). This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/)
Abstract: In Tata Steel Ltd.- India, the calcined lime produced in the Merz-kiln is stored in the respective bins for its further use in steel making at LD shops. The quality of lime controls the quality of steel, refractory life and productivity. It also helps in removing the impurities during the steel-making process. Longer and inefficient storage of calcined lime results into degradation of the lime quality due to air slaking and fines generation. To optimize the storage time, a model has been developed which tracks the live charging, storage and discharging of lime at each respective bin. The model further gives recommendations in the form of preferences for charging and discharging of the bins. Python has been used as a tool for the model development. By the integration of level 1 and level 2 automation, it has become easier to achieve this aim by using data from sensor devices. Level 1 sensors have been installed in each respective bin to get the information about the level of materials inside the bin. Further this crucial data is stored in level 2 automation system to use it in the model. Model’s result shows the live tracking of calcined-lime stored in the bins. It generates a logical layer of material inside the bin and provides the age (storage time in hours) of each layer. Based on the age of layers, model gives the preferences for charging and discharging of the bins. Eventually It provides a decision-making platform to the plant user based on preferences for better lime-storage management. The system developed also contains a HMI (Human-machine interface) where user can visualize the live tracking and preferences for each bin given by the model. The system also captures the action taken by the user based on model’s preferences. Ultimately, it optimizes the storage time and controls the lime quality inside the bin. Eventually, it also controls the degradation of lime quality due to long storage. The model has been validated quantitatively with the real-time data of processing plant captured by the level 1 sensors. The result shows that model is able to track the level of material inside the bin, age of each layer and its storage duration. The result also shows the name of preferred bins to be charged/discharged to optimize the storage duration. As per requirements, the calcined lime stored in the bins is drawn to use it in the steel-making proc-ess.
Keywords: Automation, Bin-tracking-system, Industry4.0, Quality-control.
Scope of the Article: Quality Control