Scientific and Technical Journal


ISSN Print 2221-3937
ISSN Online 2221-3805
Consider running, reducing the dynamic loads in the kinematic transmissions two-mass electromechanical system with backlash in a mode start-braking (reverse) at different initial values of clearance at the start. Before the main work cycle is carried out with reduced motor start point for the selection of the gap, and the reverse to determine the actual size of the gap. The results of the simulation.
1. Klyuchev V.I., and Terekhov V.M. Elektroprivod i avtomatizatsiya ob–shchepromyshlennykh mekhanizmov [Electric Drive and Automation of General–Purpose Machinery], (1980), Moskow, Russian Federation, Energy, 360 p. (In Russian).
2. Gerasimyak R.P., and Leshchev V.A. Analiz i sintez kranovih elektromehanicheskih system [Analysis and Synthesis of Crane Electromechanical Systems], (2008), Odessa, Ukraine, SMIL, 192 p. (In Russian).
3. Naydenko E. V. Dvuhmassovaja elektromehanicheskaja sistema s luftom v peredache v regime puska [Two-mass electromechanical system with backlash in the transmission start mode]. (2016), Electrotechnic and computer systems, Kiev, Ukraine, Vol. 21 (97), pp. 36–42 (in Russian).
4. Gerasimyak R. P., and Naydenko E. V. Nagruzki v kinematicheskih peredachah dvuhmassovoy elektromehanicheskoy sistemi v regime tormogenija [Loads in Kinematic Transfers Two–mass Electromechanical System During Braking]. (2015), Electrotechnic and computer systems, Kiev, Ukraine, Vol. 1(93), pp. 15–22 (in Russian).
5. Gerasimyak R. P., and Naydenko E. V. Dvuhmassovaja electromehanicheskaja sistema s luftom v peredache v regime tormogenija [The kinematic transmission loads of two–mass electromechanical system with gear during braking]. (2015), Electrotechnic and computer systems, Kiev, Ukraine, Vol. 18(94), pp. 62–68 (in Russian).
6. Gerasimyak, R.P., and Naydenko, E.V Upravlenie asinhrpnnim electroprivodom mehanismjv povorota, obespechivayuchee snigenie dinamicheskih nagrusok [Management of asynchronous electric drive mechanisms pivot provides a reduction of dynamic loads]. (2008), Problems of Automated Electric. Theory and Practice. – Kharkiv, Ukraine, Vol. 30, pp 111– 112 (In Russian).
7. Busher, V. V., and Naydenko E. V. Uchebniy programno–apparatniy maket dlja issledovanija dvuhmassovoy electromehanicheskoy sistemi [Educational hardware and software layout for research two–mass electromechanical system]. (2015), Electrotechnic and computer systems, Kiev, Ukraine, Vol. 20 (96), pp.16–22 (in Russian).
8. Gerasimyak R. P., and Subbotin V. V. Uluchshenie kachestva perehodnih prozessov pri vibore zazora v elektromehanicheskih sistemah [Improving the quality of transients in the selection of the gap in electromechanical systems]. (2013), Electrotechnic and computer systems, Kiev, Ukraine, Vol. 10 (86), pp.27–32 (in Russian). 9. Boiko A. A. Ohranychenye kolebanyi elementov liftovyh podemnyh mekhanyzmov za schet korrektyruiushchei obratnoi sviazy [Limiting elements hesitation lift lifting gear due to corrective feedback]. (2014), Materialy XVIII Vseukrainskoi naukovo-praktychnoi konferentsii «Suchasna osvita i nauka v Ukraini: tradytsii ta innovatsii», Kyiv, Ukraine, рр.140—145 (in Russian).
10. Smolyaninov D., Palis F., Horn P., and Grigorov O.W. Prior research of oscillation damping in cranes. Kranfachtangung Universität Magdeburg, 2002, pp. 113—128 (in Germany).
Last download:
2018-01-15 22:11:06

[ © KarelWintersky ] [ All articles ] [ All authors ]
[ © Odessa National Polytechnic University, 2014. Any use of information from the site is possible only under the condition that the source link! ]