Method and system for optimization of agglomeration of ores

The invention claimed is: 1 . A processor implemented method for optimizing the operation of an agglomeration plant, the method comprising: receiving a plurality of data as an input from one or more data sources of the agglomeration plant at a predetermined frequency, wherein the plurality of data comprises of a real-time and non-real-time data; preprocessing, via one or more hardware processors, the plurality of data; obtaining, via the one or more hardware processors, simulated data using the preprocessed data and a plurality of soft sensors, wherein the simulated data is integrated with preprocessed data to obtain integrated data; determining, via the one or more hardware processors, a first set of parameters using a physics-based wet agglomeration model and the integrated data; determining, via the one or more hardware processors, a second set of parameters using physics-based and data-driven charging models, the first set of parameters and the integrated data; determining, via the one or more hardware processors, a third set of parameters using a physics-based thermal agglomeration model, the first set of parameters, the second set of parameters and the integrated data; determining, via the one or more hardware processors, a final set of parameters using a plurality of data-driven models, the first, the second and the third set of parameters, and the integrated data; configuring, via the one or more hardware processors, an optimizer using the plurality of physics-based and data-driven models of the agglomeration plant to optimize a plurality of key performance parameters of the agglomeration plant; generating, via the one or more hardware processers, at least one recommendation using the configured optimizer, wherein the recommendations comprise of optimal settings of a plurality of manipulated variables, wherein the manipulated variables includes height of the wet agglomerate in the thermal agglomeration from lower to upper limits, a strand speed from lower to higher limits, percentage of return fines or percentage of undersize agglomerate from lower to upper limits and a reduction degradation index (RDI) of the agglomerate from lower to upper limits; providing, via the one or more hardware processors, the generated recommendations to optimize the key performance parameters of the agglomeration plant; and monitoring the key performance parameters of the agglomeration plant using self-learning physics-based and data-driven models, re-tune or re-train physics-based and data-driven models of the agglomeration plant, wherein the self-learning physics-based and data-driven models of the agglomeration plant comprising: computing, via the one or more hardware processors, a model performance index for each of the plurality of physics-based and data-driven models in real-time by comparing the model outputs with the corresponding measured variables, wherein the model performance index includes an error metrics, percentage of points error, a coefficient of determination and a customized performance metrics; determining, via the one or more hardware processors, the models responsible for model performance index exceeding the pre-determined thresholds and triggering one method out of a plurality of self-learning methods based on the model type; executing, via the one or more hardware processors, first type of self-learning method for drifted plant KPI models, wherein the drifted plant KPI model include productivity, fuel rate, yield, agglomerate quality, tumbler index, reduction degradation index, reducibility index, the plant KPI; performing self-learning of the physics-based and data-driven models of the agglomeration plant by re-training active models, wherein the active models are re-trained using recent and historical data of the agglomeration plant to obtain re-trained models; executing, via the one or more hardware processors, second type of self-learning method, wherein the active physics-based model of the thermal agglomeration unit is re-tuned in at least one level based on the sensitivity of tuning parameters to the model predictions, followed by the first type of self-learning method using recent and historical data of the agglomeration plant to obtain re-tuned and re-trained models; executing, via the one or more hardware processors, third type of self-learning method, wherein the active physics-based model of wet agglomeration and data-driven charging models are re-tuned and re-trained followed by the second type of self-learning method using recent and historical data of the agglomeration plant to obtain re-tuned and re-trained models; assessing, via the one or more hardware processors, the efficacy of executed self-learning methods by computing the model performance index using the predictions from the re-tuned and re-trained models with the corresponding measured variables; and recommending, via the one or more hardware processors, at least one re-tuned and re-trained model for activation in the agglomeration plant wherein the model performance index of the at least one re-tuned and re-trained model is below the pre-determined thresholds. 2 . The method according to claim 1 , wherein the data sources of the agglomeration plant comprise one or more of an agglomeration plant automation system, a data acquisition system, a data historian, a laboratory information management system, a manufacturing execution system or a manual input. 3 . The method according to claim 1 , wherein the preprocessing of data comprises identification and removal of outliers, imputation of missing data, and synchronization and integration of a plurality of variables from one or more data sources using the residence time of all the units of the agglomeration plant. 4 . The method according to claim 1 , wherein the plurality of soft sensors are physics-based and data-driven soft sensors comprising of: flow rates of input raw materials to the agglomeration plant, size distribution of input feed mix, mean diameter of input feed mix, chemical composition of input feed mix, and moisture content of input feed mix. 5 . The method according to claim 1 , wherein the first set of parameters comprises size distribution, mean diameter, chemical composition and water content of a wet agglomerate and the second set of parameters comprises voidage and permeability of the wet agglomerate bed, the velocity of air through the wet agglomerate bed and a size and chemical species segregation profile of wet agglomerate bed. 6 . The method according to claim 1 , wherein the third set of parameters comprises: distributions of temperature and a plurality of chemical species at different heights of the bed and lengths of a thermal agglomeration unit, a velocity and flow rate of inlet air and gas at different lengths of the thermal agglomeration unit, temperature, velocity and flow rate of outlet gas from different lengths of the thermal agglomeration unit, a velocity and thickness of the flame front at different lengths of the thermal agglomeration unit, temperature and flow rate of the exhaust gas from different lengths of the thermal agglomeration unit, length and location of burn through point in the thermal agglomeration unit, and temperature of agglomerate discharged from the thermal agglomeration unit. 7 . The method according to claim 1 , wherein the final set of parameters comprises: productivity, yield, efficiency, fuel rate and percentage of undersized agglomerates from the agglomeration plant, and size distribution, mean diameter, tumbler index, abrasion index, cold compressive strength, reduction degradation index, reducibility index, and softening melting parameters of the agglomerate. 8 . The method according to claim 1 further comprisin