Abstract
In this research article, experimental study was carried out to obtain the heat transfer characteristics between a submerged horizontal tube bundle and a fluidized bed in a large-scale circulating fluidized bed (CFB) boiler with an external heat exchanger (EHE). The operational parameters in the tube EHE were measured during performance tests at variable load conditions. The average heat transfer coefficient (HTC) was calculated using a mechanistic heat transfer model based on packed renewal theory. The heat transfer characteristics are considered in terms of heat transfer mechanisms such as emulsion phase convection, gas convection and also thermal radiation. The obtained heat transfer data exhibit a maximum value with variation mean bed particle size irrespective of pressure. The results showed that the average HTC increases with a decrease of the Sauter mean particle diameter and with the increase of the fluidizing number as a result of good mixing dynamics in emulsion phase (i.e. emulsion wall contact time, bubble fraction in the bed). Based on the heat transfer data, empirical correlations are proposed for predicting a heat transfer coefficient from fluidized bed to horizontal tube bundle. The mechanistic heat transfer model predicted the average HTC in sufficiently good agreement with CFB boiler data accessible in the literature.
Highlights
Knowledge about the heat transfer coefficient from bubbling fluidized bed particles to the tube heat exchanger is necessary for an optimal/more reliable design and scaling-up of heat transfer surfaces in processes where the control of temperature plays an essential role from the point of view of proper operation and optimum performance of circulating fluidized bed (CFB) boilers
The empirical model of heat transfer coefficient used the parameters of solids and gas in a fluidized bed heat exchanger, which were recorded at different CFB boiler loads
The influence of operating parameters on the heat absorption characteristics of an external tube heat exchanger in a 1296t/h circulating fluidized bed boiler are studied by means of heat transfer correlations developed by us
Summary
Knowledge about the heat transfer coefficient from bubbling fluidized bed particles to the tube heat exchanger is necessary for an optimal/more reliable design and scaling-up of heat transfer surfaces in processes where the control of temperature plays an essential role from the point of view of proper operation and optimum performance of CFB boilers. This is especially important in the case of CFB combustors fired with various fuel types, at turn down boiler loads and SO2 and NOx emission control levels. The obtained heat transfer data can be used to validate empirical correlations for the design and scale-up of heat transfer surfaces for commercial CFB boilers and bridge a gap in the accessible CFB & BFB (bubbling fluidized bed) literature
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