Compressed air quality increase for rolling stock pneumatic systems based on energy efficiency

Ripol-Saragosi, T.; Ripol-Saragosi, L.; Smychok, I.

doi:10.20858/tp.2018.13.4.2

Artykuł - szczegóły

Tytuł artykułu

Compressed air quality increase for rolling stock pneumatic systems based on energy efficiency

Autorzy

Ripol-Saragosi T. , Ripol-Saragosi L. , Smychok I.

Treść / Zawartość

Pełne teksty:

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DOI

10.20858/tp.2018.13.4.2

Warianty tytułu

Języki publikacji

Abstrakty

The energy efficiency increase problem for railway rolling stock pneumatic systems compressed air preparation is directly connected with its purification and drying technology choice. In the presented materials in the article, the authors find a solution to the problem based on realization analysis of different factors that affect compressed air quality, purification and drying technology choice, as well as based on energy efficiency analysis. To realize the energy-saving events at railway rolling stock compressed air preparation, the authors suggest performing factor analysis influencing on compressed air purification method choice to consider pneumatic system as a module scheme and to employ the modernized construction of the locomotive main tanks.

Słowa kluczowe

compressed air compressor rolling stock drying purification

sprężone powietrze sprężarka pojazd szynowy suszenie oczyszczanie

Wydawca

Wydawnictwo Politechniki Śląskiej

Czasopismo

Transport Problems

Rocznik

2018

Tom

T. 13, z. 4

Strony

13--21

Opis fizyczny

Bibliogr. 15 poz.

Twórcy

autor

Ripol-Saragosi T.

ripol-saragosi@mail.ru

Rostov State Transport University Narodnogo Opolcheniya Sq., 2, 344008, Rostov-on-Don, Russia

autor

Ripol-Saragosi L.

Rostov State Transport University Narodnogo Opolcheniya Sq., 2, 344008, Rostov-on-Don, Russia

autor

Smychok I.

Rostov State Transport University Narodnogo Opolcheniya Sq., 2, 344008, Rostov-on-Don, Russia

Bibliografia

1. Ferrero, D. & Gamba, M. & Lanzini, A. & Santarelli, M. et al. Energy Procedia Power-to-Gas Hydrogen: techno-economic assessment of processes towards a multi-purpose energy carrier. In: Proceedings of 71st Conference of the Italian Thermal Machines Engineering Association. Turin: ATI2016. 14-16 September 2016. P. 50-57.
2. White Jr., D. Compressed Air and Gas Purification and Fractionation for High Purity Applications by Improved PSA Processes. Separation Science and Technology. 2008. Vol. 43. No. 9-100. P. 2298-2306.
3. Iwainsky, H. & Beeck, U. & Ivan, J. Redundant Compressed Air Supply for Trams and Railcars. Fahrzeuge rolling-stock. 2016. Vol. 140. P. 75-79.
4. Ruppelt, E. & Bahr, M. Efficient compressed air drying. 2015. Kaiser kompressoren. Technical Press article. Available at: http://en.kaeser.co.th/m/Advisor/Technical_articles/articles/hybitec.asp
5. Cost Saving Air Dryer Technology. Available at: https://www.bryair.com/news-andevents/articles/cost-saving-air-dryer-technology.
6. Drying Compressed Air 2011. Lancaster: Parker Hannifin Corporation. 2011. Bulletin M261K. Available at: http://www.parker.com/Literature/Gas%20Separation%20and%20Filtration%20Division/PDF%20Files/DryingCompressedAirGuide.pdf.
7. Curtin, K. Clean Air is Crucial for Optimal Pneumatics. Design World Staff. 2011. Vol. 1. P. 35-41.
8. Chris, E. Improving Compressed Air Quality. Available at: http://www.izsystems.com/articles/detail/improving-compressed-air-quality-by-eliminating-mo
9. Cleveland compressed air services. Aug 24, 2016. The benefits of different types of compressed air dryers. Available at: https://clevelandcompressors.com.au/the-benefits-of-different-types-ofcompressed- air-dryers/.
10. Goodarzia, G. & Dehghani, S. & Akbarzadeh, A. & Date, A. Energy saving opportunities in air drying process in high-pressure compressors. In: Proceedings of 1st International Conference on Energy and Power, ICEP2016. Melbourne: RMIT University. 14-16 December 2016. P. 428-433.
11. Kairouz, K. & Jazdzyk, D. & Al Musawi, S. Energy efficiency with compressed air. Processing. 2016. Vol. 4. P. 111-115.
12. Energy savings through proper use of pneumatics – Fluid Power Journal. Available at:https://www.festo.com/rep/en-us_us/assets/pdf/US_Articles_FluidPowerJournal_March2014.pdf.
13. Yan, F., Rinoshika, A. An experimental study on a horizontal energy-saving pneumatic conveying system. In: Proceedings of the 7th World Congress on Particle Technology (WCPT7). Jiangsu University of Science and Technology, School of Mechanical Engineering, Department of Mechanical Systems Engineering. 2016. P. 75-86.
14. Патент № 2514871. Риполь-Сарагоси, Т.Л. & Риполь-Сарагоси, Л.Ф. Резервуар для осаждения и удаления влаги из сжатых газов. [In Russian: Patent No. 2514871. Ripol-Saragosi, T.L. & Ripol-Saragosi, L.F. Tank for condensation and removal from compressed gases].
15. ГОСТ Р 53977-2010 Сжатый воздух пневматических систем железнодорожного подвижного состава. Требования к качеству, 7 с. [In Russian: Compressed air of railway rolling stock pneumatic systems. Requirements for quality, 7 p.].

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).

Typ dokumentu

Bibliografia

Identyfikator YADDA

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