FUEL PLANNING PROBLEMS FOR FLIGHTS, PLANNED VIA STANDARD ARRIVAL ROUTES (STAR) WITH DELAY LEGS

The article deals with the fuel planning problems for flights planned via standard arrival routes (STAR), with delay legs. Implementation of new standard arrival routes based on area navigation principles leads to increasing airspace capacity and reducing workload for both flight crews and air traffic controllers. More and more air navigation service providers implement modern STARs which include delay legs as their components. Delay legs are being used as modern alternative to delay actions performed with short time holding patterns or radar vectoring procedures. But, new STAR types’ implementation without changing fuel planning procedures has led to fuel consumption increase. The nature of problem is shown in the article with reference to recently designed, published and implemented Pulkovo airport new standard arrival routes with delay legs. The calculations made with the use of automated flight planning systems and shown extra fuel consumption are given. Contributing negative factors are described. Suggested methods of solving the problems allow avoiding extra fuel consumption and reducing pollution. The procedure for using the new approach to planning and performing flight via STARs with delay legs is described. Implementation of the new approach in arrival trajectory design, flight planning and flight performance via standard arrival routes with delay legs is actual for the existing arrival routes and the routes being projected.

аir traffic, arrival path, ATM procedures, fuel consumption, flight planning

1. Assorov, N.A. (2015). Analiz organizatsi i vozdushnogo dvizheniya v nekotorykh krupnikh aeroportakh mira [Analysis of air traffic management in some major airports of the world]. The Scientific Bulletin of the Moscow State Technical University of Civil Aviation, no. 221, pp. 5–12. (in Russian)

2. Divak, N.I. and Nechaev, E.E. (2015). Analiz struktury vozdushnogo prostranstva MVZ [Analysis of the proposed airspace stricter of Moscow ATM]. The Scientific Bulletin of the Moscow State Technical University of Civil Aviation, no. 221, pp. 13–17. (in Russian)

3. Kumkov, S.I., Pyatko, S.G. and Spiridonov, A.A. (2018). Issledovaniye standartnoy i veernoy skhem zaderzhki vozdushnikh sudov v zone podkhoda [Investigation of standard and pointmerge schemes of aircraft delay in approach zone]. The Scientific Bulletin of The State Scientific Research Institute of Civil Aviation (GosNII GA), no. 20(331), pp. 63–73. (in Russian)

4. Shaw, C. and Ivanescu, D. (2018). Fast-time simulation of Point Merge indicates significant improvements [Electronic resource]. Available at: https://www.eurocontrol.int/eec/public/ standard_page/EEC_News_2008_1_PM.html (accessed: 14.10.2018).

5. Hivritch, I.G., Mironov, N.F. and Belkin, A.M. (1984). Vozdushnaya navigatsiya [Air navigation]. Uchebnoye posobiye [A tutorial]. Moscow: Transport, 328 p. (in Russian)

6. Eger, S.М., Matvienko, A.M. and Shatalov, I.A. (1999). Osnovy aviatsionnoy tekhniki [The basics of aviation technics]. 2-e izd., pererab. i dop. [Second edition, revised and enlarged]. Moscow: MAI, 575 p. (in Russian)

7. Lugovoi, V.G. (2017). Primeneniye protsedury Point Merge v uslovuyakh neravnomernogo raspredeleniya potokov pribivayuschcikh vozdushnikh sudov [Point merge procedure performance during unsteady arriving traffic flow distribution situation]. Vestnik SPBGU GA [Bulletin of the SPBGUGA], no. 4(17), pp. 25–37. (in Russian)

8. Divak, N.I. (2014). K voprosu o razrabotke novoy struktury vozdushnogo prostranstva Moskovskoy vozdushnoy zony [On the development of a new structure of Moscow area airspace]. The Scientific Bulletin of the Moscow State Technical University of Civil Aviation, no. 209(11), pp. 67–71. (in Russian)

9. Glukhov, Y.E. and Konovalov, A.E. (2014). Alternativnyy variant reorganizatsii struktury vozdushnogo prostranstva v moskovskom uzlovom dispetcherskom rayone [The alternative variant of Moscow terminal maneuvering area restructurisation]. The Scientific Bulletin of the Moscow State Technical University of Civil Aviation, no. 209(11), pp. 60–66. (in Russian)

10. Zlobin, A. (2018). Dorogoe nebo. Aviabilety dorozhayut iz-za rosta tsen na kerosin [Expensive sky. The airline tickets are growing in price owing to the aircraft fuel price increase] [Electronic resource]. Available at: http://www.forbes.ru/biznes/365151-dorogoe-nebo-aviabilety-dorozhayut-iz-za-rosta-cen-na-kerosin (accessed: 16.10.2018). (in Russian)

11. Vozdvizhenskaya, A. and Shadrina, T. (2017). Bilet pakhnet kerosinom [Ticket smells fuel]. Rossiyskaya gazeta, no. 267. (in Russian)

12. Ivanova, A.R. (2017). Vliyaniye aviatsii na okruzhayushchuyu sredu i mery po oslableniyu negativnogo vozdeystviya [Aviation impact on environment and the measures for mitigation of negative effect]. Proceedings of Hydrometcentre of the Russian Federation, iss. 365, pp. 5–14. (in Russian)