Abstract
Industrial boiler damage is a common phenomenon encountered in boiler operation which usually lasts several decades. Since boiler shutdown may be required because of localized failures, it is crucial to predict the most vulnerable parts. If damage occurs, it is necessary to perform root cause analysis and devise corrective measures (repairs, design modifications, etc.). Boiler tube bundles, such as those in superheaters, preheaters and reheaters, are the most exposed and often the most damaged boiler parts. Both short-term and long-term overheating are common causes of tube failures. In these cases, the design temperatures are exceeded, which often results in decrease of remaining creep life. Advanced models for damage evaluation require temperature history, which is available only in rare cases when it has been measured and recorded for the whole service life. However, in most cases it is necessary to estimate the temperature history from available operation history data (inlet and outlet pressures and temperatures etc.). The task may be very challenging because of the combination of complex flow behaviour in the flue gas domain and heat transfer phenomena. This paper focuses on estimating thermal load non-uniformity on superheater tubes via Computational Fluid Dynamics (CFD) simulation of flue gas flow including heat transfer within the domain consisting of a furnace and a part of the first stage of the boiler.
Highlights
Boiler can be described as a device which produces steam using heat received from chemical reaction
Choice of the main boiler components depends on fuel type which is burnt and the boiler size is based on required amount of steam production for consequent use in turbine or other processes
Important distinction between various fuels is in their flue gas composition, since gas burning produces almost no ash in comparison with liquid and solid fuels that produce a lot of ash, often resulting in significant problems [1, 2]
Summary
Boiler can be described as a device which produces steam (or in some cases hot water) using heat received from chemical reaction. Choice of the main boiler components depends on fuel type which is burnt and the boiler size is based on required amount of steam production for consequent use in turbine or other processes. There are three basic types of fuels which are usually burnt: gas (natural gas, methane...), liquid (various oils) and solid (dark and brown coal ...). Important distinction between various fuels is in their flue gas composition, since gas burning produces almost no ash in comparison with liquid and solid fuels that produce a lot of ash, often resulting in significant problems [1, 2]. Demand for boilers with higher standards, higher efficiency and possibility of burning various fuel types, and with lower impact on the environment, is more relevant than ever
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