Investigation of Low-Temperature Lean Combustion Characteristics in Power Plants with External Heating of Components

Investigation of Low-Temperature Lean Combustion Characteristics in Power Plants with External Heating of Components

An integral part of any open-type gas turbine plant is a low-emission combustion chamber, which is usually two-zone and cooled. One of the ways to reduce emission of harmful substanc-es is organizing low-emission low-temperature lean combustion with external heating of compo-nents. This paper invest...

Full description

Saved in:
Bibliographic Details
Main Authors: Bachev N.L., Shilova A.A., Matyunin O.O., Betinskaya O.A.
Format: Article
Language:English
Published: Academy of Sciences of Moldova 2021-06-01
Series:Problems of the Regional Energetics
Subjects:
low-temperature lean combustion
external heating of components
stable position of turbulent flame
relative flow rate.
Online Access:https://journal.ie.asm.md/assets/files/11_02_50_2021.pdf
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:An integral part of any open-type gas turbine plant is a low-emission combustion chamber, which is usually two-zone and cooled. One of the ways to reduce emission of harmful substanc-es is organizing low-emission low-temperature lean combustion with external heating of compo-nents. This paper investigates the effect of external heating of air and fuel gas on expansion of the lower combustion limit and stable flame position in a single-zone uncooled combustion chamber of a microgas turbine power plant. Stable position of the flame front in combustion chambers of this type mainly depends on the ratio between the average flow rate of the combus-tible-air mixture and the rate of turbulent combustion. This ratio depends on thermal, gas-dynamic, thermochemical and geometric factors. The purpose of this work is to substantiate the possibility of using the relative flow rate as a generalized characteristic. This goal was achieved in processing a large amount of published experimental data and numerical modeling of low-temperature combustion of lean mixtures. The most significant research result is determination of the range of relative flow rate (gk = 0.3…3.5·10-4 kg⁄s∙N), at which it is possible to ensure sta-ble flame position in a single-zone combustion chamber. Significance of the obtained results lies in the fact that using the relative flow rate makes it possible to quickly determine and analyze the geometric and gas-dynamic parameters and characteristics of turbulent combustion in com-bustion chambers of micro-gas turbine power plants.
ISSN:1857-0070

Similar Items