Numerical analysis and thermal comfort optimization of different ventilation systems for commercial aircraft cabins / Ahmed Mohamed Farag Abdelbary ; Supervised Essam E. Khalil , Mohamed Ali Hassan , Omar Ahmed Huzayyin

By:

Ahmed Mohamed Farag Abdelbary

Contributor(s):

Material type: Text

TextLanguage: English Publication details: Cairo : Ahmed Mohamed Farag Abdelbary , 2015Description: 195 P. : charts , facsimiles ; 30cmOther title:

التحليل العددي وتقييم الراحة الحرارية لأنظمة التهوية المختلفة بكابينة طائرة [Added title page title]

Subject(s):

Available additional physical forms:

Issued also as CD

Dissertation note: Thesis (Ph.D.) - Cairo University - Faculty of Engineering- Department of Mechanical Power Engineering Summary: The ventilation systems in commercial aircraft cabins are important for providing a healthy and comfortable environment for the passengers and crew. The high density and close proximity of passengers in the modern aircraft cabin exposes them to the risk of contracting airborne diseases such as flu, severe acute respiratory syndrome (SARS), chickenpox and tuberculosis. Current aircraft personalized ventilation (PV) systems still cannot ensure a constant circulation of fresh humidified air around each passenger{u2019}s breathing zone to shield them from airborne contaminants. It is proposed to investigate the use of PV systems in aircraft cabins using computational fluid dynamics (CFD) techniques. This would lead to better understanding and an improved microclimate around the breathing zone of each passenger. A comprehensive analysis framework based on the American Society of Heating, Refrigerating and Air-conditioning Engineers (ASHRAE) thermal comfort assessment models has been developed. The components of the framework consists of the age of air, predicted mean vote (PMV), predicted percentile dissatisfied (PPD), draught risk (PD), contaminant aerosol transport model and a humidity

Tags from this library: No tags from this library for this title. Log in to add tags.

Average rating: 0.0 (0 votes)

Holdings
Item type	Current library	Home library	Call number	Copy number	Status	Date due	Barcode
Thesis	قاعة الرسائل الجامعية - الدور الاول	المكتبة المركزبة الجديدة - جامعة القاهرة	Cai01.13.11.Ph.D.2015.Ah.N (Browse shelf(Opens below))		Not for loan		01010110066561000
CD - Rom	مخـــزن الرســائل الجـــامعية - البدروم	المكتبة المركزبة الجديدة - جامعة القاهرة	Cai01.13.11.Ph.D.2015.Ah.N (Browse shelf(Opens below))	66561.CD	Not for loan		01020110066561000

Browsing المكتبة المركزبة الجديدة - جامعة القاهرة shelves Close shelf browser (Hides shelf browser)

Previous	No cover image available	No cover image available	No cover image available	No cover image available	No cover image available	No cover image available	No cover image available	Next
Previous	Cai01.13.11.Ph.D.2015.Ah.E Effect of using gaseous fuels on cold starting and warm up characteristics of SIE at low ambient temperature /	Cai01.13.11.Ph.D.2015.Ah.N Numerical investigation of indoor air quality in healthcare facilities /	Cai01.13.11.Ph.D.2015.Ah.N Numerical investigation of indoor air quality in healthcare facilities /	Cai01.13.11.Ph.D.2015.Ah.N Numerical analysis and thermal comfort optimization of different ventilation systems for commercial aircraft cabins /	Cai01.13.11.Ph.D.2015.Ah.N Numerical analysis and thermal comfort optimization of different ventilation systems for commercial aircraft cabins /	Cai01.13.11.Ph.D.2015.Al.N Numerical analysis of an external store separation from a fighter aircraft /	Cai01.13.11.Ph.D.2015.Al.N Numerical analysis of an external store separation from a fighter aircraft /	Next

Thesis (Ph.D.) - Cairo University - Faculty of Engineering- Department of Mechanical Power Engineering

The ventilation systems in commercial aircraft cabins are important for providing a healthy and comfortable environment for the passengers and crew. The high density and close proximity of passengers in the modern aircraft cabin exposes them to the risk of contracting airborne diseases such as flu, severe acute respiratory syndrome (SARS), chickenpox and tuberculosis. Current aircraft personalized ventilation (PV) systems still cannot ensure a constant circulation of fresh humidified air around each passenger{u2019}s breathing zone to shield them from airborne contaminants. It is proposed to investigate the use of PV systems in aircraft cabins using computational fluid dynamics (CFD) techniques. This would lead to better understanding and an improved microclimate around the breathing zone of each passenger. A comprehensive analysis framework based on the American Society of Heating, Refrigerating and Air-conditioning Engineers (ASHRAE) thermal comfort assessment models has been developed. The components of the framework consists of the age of air, predicted mean vote (PMV), predicted percentile dissatisfied (PPD), draught risk (PD), contaminant aerosol transport model and a humidity

Issued also as CD

There are no comments on this title.

to post a comment.