Exhaust Toxicity of a Gas Turbine Engine with Step-by-Step Post-Treatment: the Environmental Aspect of the Impact on Atmosphere

Bekele, Desta Abebe; Zagorsky, Vladimir A.; Hailu, Dubbessa Mulubirhan

doi:10.12912/27197050/146242

Artykuł - szczegóły

Tytuł artykułu

Exhaust Toxicity of a Gas Turbine Engine with Step-by-Step Post-Treatment: the Environmental Aspect of the Impact on Atmosphere

Autorzy

Bekele Desta Abebe , Zagorsky Vladimir A. , Hailu Dubbessa Mulubirhan

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

DOI

10.12912/27197050/146242

Warianty tytułu

Języki publikacji

Abstrakty

The development of technology imposes new, higher requirements on those that exist. Encourages the creation of new materials. In order to reduce the weight of aircraft structures, for example, multi-layer structures that combine lightness, rigidity, and strength are used. For many areas of technology is necessary such that combine structural strength with high electrical, thermal, optical, and other properties. Regulating the structure of traditional materials is a promising way to improve quality. Thus, by means of directed crystallization of steels and alloys, cast parts are obtained, for example, gas turbine blades, consisting of crystals oriented relative to the main stresses in such a way that the edges of the grains are unobtrusive. Directional crystallization allows increasing plasticity and durability several times. The greatest environmental pollution occurs in the area of airports (airfields) during the landing and take-off of aircraft, as well as the warming up of their engines. When engines are running on take-off and landing, the maximum amount of carbon monoxide and hydrocarbon compounds enter the surrounding environment, and the maximum amount of nitrogen oxides enter the flight process. A jetliner that makes a transatlantic flight requires from 50 to 100 tons of this gas. On the territory of the airfield, engines are launched, taxiing, take-off, and landing of aircraft, during which harmful exhaust products of aviation engines, pre-launch (waiting location) and on the runway enter the atmosphere.

Słowa kluczowe

modeling air pollution environment monitoring

Wydawca

Lubelski Oddział Polskiego Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology
WNGB Wydawnictwo Naukowe

Czasopismo

Ecological Engineering & Environmental Technology

Rocznik

2022

Tom

Vol. 23, iss. 2

Strony

193--198

Opis fizyczny

Bibliogr. 15 poz., rys., tab.

Twórcy

autor

Bekele Desta Abebe

abe_desta@mail.ru

Samara National Research University, Moskovskoye Hwy, 34, Samara, Samara Oblast, 443086, Russian Federation

https://orcid.org/0000-0003-2921-4611

autor

Zagorsky Vladimir A.

Samara National Research University, Moskovskoye Hwy, 34, Samara, Samara Oblast, 443086, Russian Federation

https://orcid.org/0000-0002-0380-9097

autor

Hailu Dubbessa Mulubirhan

Samara National Research University, Moskovskoye Hwy, 34, Samara, Samara Oblast, 443086, Russian Federation

https://orcid.org/0000-0001-7413-4923

Bibliografia

1. Franke M.M., Hilbinger R.M., Lohmüller A., Singer R.F. 2013. Process of ecological. Technol., 213, 2081–2088.
2. Gribust I. 2018. Regulation of the state of plantings in the anthropogenically transformed territories: the principle of dendrological diversity. World Ecology Journal, 8(2), 11–21. https://doi.org/https://doi.org/10.25726/NM.2018.2.2.002
3. Guo X., Fu H., Sun J. 1997. Regulation of ecological aspects. Metall. Mater. Trans. 28A, 997–1009.
4. Jarczyk G., Szeliga D. Giesserei-Praxis. 2013. Ecological vision, 11, 468–473.
5. Kruzhilin S., Baranova T., Mishenina M., Zaitseva M. 2018. Regional specificity creation of protective afforestations along highways. World Ecology Journal, 8(2), 22–32. https://doi.org/https://doi.org/10.25726/NM.2018.2.2.003
6. Kubiak K., Szeliga D., Sieniawski J. and Onyszko A. 2015. The unidirectional crystallization of metals and alloys (Turbine blades). Elsevier, 413–457.
7. Miller J.D., Pollock T.M. 2014. Ecological of gas and exhaust systems, 78, 23–36.
8. Mirjalili S., Mirjalili S. M., Lewis A. 2014. Grey wolf optimizer. Advances in Engineering Software, 69(7), 46–61.
9. Pollock T.M., Murphy W.H. 1996. Aspects of neutralization gas exhaust, 27A, 1081–1-94.
10. Reed R. C. 2006. The Superalloys Fundamentals and Applications, Cambridge University Press, Cambridge, 1–18.
11. Szeliga D., Kubiak K., Sieniawski J.J. 2016. Exhaust of gas turbine technology, 232, 18–26.
12. Wang F., Ma D., Bogner S., Bührig-Polaczek A. 2016. Neutralization exhaust gas and ecological aspects, 47A, 2376–2386.
13. Xu H., Ma J., Zhao H. 2018. Macroscopic fuel reactor modelling of a 5 kWth, interconnected fluidized bed for in-situ gasification chemical looping combustion of coal. Chemical Engineering Journal, 348(9), 978–991.
14. Yang X. L., Lee P.D., Brooks R.F., Wunderlich R. 2014. Ecology and newest engines. The Mineral, Metals and Materials Society, Pittsburgh, 951–958.
15. Zhao F., Shao Z., Wang J., Zhang C. 2017. A hybrid optimization algorithm based on chaotic differentia evolution and estimation of distribution. Computational and Applied Mathematics, 36(1), 433–458.

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-6acc202b-2e5e-4588-adfd-91f0980ec5e5