Abstract
Machine learning has received increased recognition for applications in engineering such as the thermal engineering discipline due to its abilities to circumvent thermodynamic simulation approaches and capture complex inter-dependencies. There have been recent headways to couple deep learning models to process simulations, given the deeper insight they can provide. The present study entails the development of a mixture density network (MDN) capable of predicting effective heat transfer coefficients for the various heat exchanger components of a utility scale boiler. Large boilers are susceptible to dead zones and other anomalous phenomena that influence performance and manifest as multimodalities in the measured data, which system-level 1D process models struggle to capture. The overall water-side heat load calculation, as well as mass and energy balances around the components were done to determine the heat transfer coefficients at each stage of the boiler using historic sensor data. The measured data was then used to train a deep learning model capable of outputting predicted heat transfer coefficients and local model uncertainty. The predictive model can be coupled to a water circuit process model which can be used to study aspects such as metal temperatures and operating philosophies at the different operating loads of the plant.
Highlights
Monitoring the thermal performance of boiler heat exchangers is crucial to ensure safe and efficient operation of power plants
Boiler tubes are subjected to extreme conditions in coal-fired power plants which can lead to mechanical failures
The present study proposes a data-driven method of determining effective heat transfer coefficients with minimal plant data using a mixture density network (MDN) approach
Summary
Monitoring the thermal performance of boiler heat exchangers is crucial to ensure safe and efficient operation of power plants. Boiler tubes are subjected to extreme conditions in coal-fired power plants which can lead to mechanical failures. These failures can be caused by a number of problems such as, slagging, fouling, caustic embrittlement, fireside corrosion and thermal fatigue failure with the latter being one of the main reasons for unwanted plant downtime [1],[2]. Increased levels of deposition and non-uniform flow leads to higher heat exchanger outlet temperatures which results in higher levels of slagging on downstream heat exchangers, lower boiler thermal efficiency and higher fuel demand [4]. A model capable of capturing actual plant thermal performance would enable studying historic heat exchanger metal temperatures to estimate residual life and quantify effects of boiler input parameters on heat exchanger performance
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