Discharge coefficient and jet deflection studies for combustor liner air-entry holes

Discharge coefficient and jet deflection studies for combustor liner air-entry holes

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In the simple tubular combustor system for turbojets and ramjets, figure 1, at the primary zone it is required to achieve a high heat release and stable flame. At the dilution cone to have a good air flow distribution (Ref. I ), and adequate penetration. In both zones these requirements needs to be...

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Main Author: Kaddah, K. S. M. I.
Language:en
Published: Cranfield University 2013
Online Access:http://dspace.lib.cranfield.ac.uk/handle/1826/7834
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spelling ndltd-CRANFIELD1-oai-dspace.lib.cranfield.ac.uk-1826-78342013-04-19T15:26:00ZDischarge coefficient and jet deflection studies for combustor liner air-entry holesKaddah, K. S. M. I.In the simple tubular combustor system for turbojets and ramjets, figure 1, at the primary zone it is required to achieve a high heat release and stable flame. At the dilution cone to have a good air flow distribution (Ref. I ), and adequate penetration. In both zones these requirements needs to be with the minimum total pressure loss for high overall efficiency, short liner length, and light simple construction (Ref. 2 ). The air flow distribution between these two zones is still the main problem of the design engineer. But the flow of annular air to these zones is governed by the geometry of the eyetem, hole coonetry and dicehargo coefficient of these holes. For light construction and adequate penetration, the main governing factor is the deflection angle of the liner jots. Cont/d.Cranfield University2013-02-15T10:18:48Z2013-02-15T10:18:48Z1964-06Thesis or dissertationDoctoralPhDhttp://dspace.lib.cranfield.ac.uk/handle/1826/7834en
collection NDLTD
language en
sources NDLTD
description In the simple tubular combustor system for turbojets and ramjets, figure 1, at the primary zone it is required to achieve a high heat release and stable flame. At the dilution cone to have a good air flow distribution (Ref. I ), and adequate penetration. In both zones these requirements needs to be with the minimum total pressure loss for high overall efficiency, short liner length, and light simple construction (Ref. 2 ). The air flow distribution between these two zones is still the main problem of the design engineer. But the flow of annular air to these zones is governed by the geometry of the eyetem, hole coonetry and dicehargo coefficient of these holes. For light construction and adequate penetration, the main governing factor is the deflection angle of the liner jots. Cont/d.
author Kaddah, K. S. M. I.
spellingShingle Kaddah, K. S. M. I.
Discharge coefficient and jet deflection studies for combustor liner air-entry holes
author_facet Kaddah, K. S. M. I.
author_sort Kaddah, K. S. M. I.
title Discharge coefficient and jet deflection studies for combustor liner air-entry holes
title_short Discharge coefficient and jet deflection studies for combustor liner air-entry holes
title_full Discharge coefficient and jet deflection studies for combustor liner air-entry holes
title_fullStr Discharge coefficient and jet deflection studies for combustor liner air-entry holes
title_full_unstemmed Discharge coefficient and jet deflection studies for combustor liner air-entry holes
title_sort discharge coefficient and jet deflection studies for combustor liner air-entry holes
publisher Cranfield University
publishDate 2013
url http://dspace.lib.cranfield.ac.uk/handle/1826/7834
work_keys_str_mv AT kaddahksmi dischargecoefficientandjetdeflectionstudiesforcombustorlinerairentryholes
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