Heat Exchange of Tubular Surfaces in a Bubbling Fluidized Bed

A practical guide through the latest research, developments, data and experimental studies on the boiling bed

Oleksandr Redko (Author), Andriy Redko (Author)

9780128226384, Elsevier Science

Paperback, published 30 August 2023

286 pages
22.9 x 15.2 x 1.9 cm, 0.483 kg

Heat Exchange of Tubular Surfaces in a Bubbling Boiling Bed bridges the gap surrounding the study of a boiling bed of large particles with smooth and ribbed pipes, as well as pipe bundles. The book's authors combine results from experimental studies with their varied practical experience in fields of boiling bed applications across various disciplines such as chemical, pharmacological, metallurgical and power engineering industries. This book provides readers with a deep practical understanding of how to calculate the heat engineering parameters of ribbed pipe bundles in a boiling bed, along with the hydrodynamics of the boiling bed.

Researchers and experts involved in the design, development and operation of boiling bed apparatus will follow step-by-step methods and procedures to gain knowledge of the hydrodynamic and heat exchange elements of the boiling bed which can be applied to their own settings. The effect of gas velocity, size and properties of the dispersed material, the geometric characteristics of the pipe bundle is also presented, alongside data on the effect of high temperature and high pressure of gas in a dispersed system on heat exchange intensity.

1. Hydrodynamics of a fluidized bed with immersed surfaces
2. Methods and experimental facilities for the study of combustion and heat transfer processes in fluidized bed furnaces
3. Heat exchange of ribbed tubes in a fluidized bed of large particles in relation to the conditions of fuel combustion
4. Heat transfer, aerodynamic resistance and erosion wear of bundles of ribbed tubes in a fluidized bed of large particles
5. Intensification of heat exchange between a fluidized bed and a bundle of horizontal tubes

Subject Areas: Energy technology & engineering [TH], Thermodynamics & heat [PHH]