Abstract
The digitization of manufacturing processes has led to an increase in the availability of process data, which has enabled the use of data-driven models to predict the outcomes of these manufacturing processes. Data-driven models are instantaneous in simulate and can provide real-time predictions but lack any governing physics within their framework. When process data deviates from original conditions, the predictions from these models may not agree with physical boundaries. In such cases, the use of first-principle-based models to predict process outcomes have proven to be effective but computationally inefficient and cannot be solved in real time. Thus, there remains a need to develop efficient data-driven models with a physical understanding about the process. In this work, we have demonstrate the addition of physics-based boundary conditions constraints to a neural network to improve its predictability for granule density and granule size distribution (GSD) for a high shear granulation process. The physics-constrained neural network (PCNN) was better at predicting granule growth regimes when compared to other neural networks with no physical constraints. When input data that violated physics-based boundaries was provided, the PCNN identified these points more accurately compared to other non-physics constrained neural networks, with an error of <1%. A sensitivity analysis of the PCNN to the input variables was also performed to understand individual effects on the final outputs.
Highlights
Accepted: 16 April 2021The manufacturing industry’s adoption of digitization has led to rapid growth in the available data [1]
A framework was presented in which physics-based constrains were introduced inside a neural network for a granulation process
The physics-constrained neural network (PCNN) used was benchmarked against pure data-driven neural network and it showed improved predictions on identifying granule growth regimes during the granulation process
Summary
The manufacturing industry’s adoption of digitization has led to rapid growth in the available data [1] This in turn has led to a foray of data-driven methods being used to predict the process operations [2]. The scale of data collection in other chemical industries is considerably smaller and may not provide sufficient data for machine learning methods to perform efficiently. Wet granulation is a process of agglomeration of smaller particles into larger granules to improve flowability and compressibility It is considered as an important unit operation in the solid processing industry [18]. The particles are bound together by a combination of capillary and viscous forces This process is of economic importance to the pharmaceutical industry as it improves several characteristics of a tablet such as dissolution, hardness, etc. One of the earliest attempts to model the granulation process proposed by [20], where the researchers employed the use of population balance equations
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