The paper objective is to solve the issues related to the increase of reliability, profitability, and safety of modern washing ma-chines on the basis of decrease in dynamic loads under whizzing. The principles of forming operation factors in the liquid self-balancing device (SBD) with the displaced fluid (on which de-sign a number of patents are received) when passing a resonance zone under whizzing are considered. A comparative analysis of the SBD function implementation for the conditions of forming an adequate force response to the force input for two earlier es-tablished most rational conditions: for the force generated by resonance, and if reached the maximum unbalanced force, is carried out. The dependences of the SBD internal capacity trav-erse on the design factors of the SBD and the cleaning unit sus-pension system, and also on the operation parameters of the ex-traction process, are obtained. The research results are submitted in diagrams. The results analysis allows drawing the conclusions on the obtained data application perspectiveness to ensure maxi-mum efficiency of the process of balancing irregular masses of textiles in the drum during the whizzing cycle.
vibrations of washing machines, self-balancing de-vice, resonance, balancing, vibroactivity, whizzing, vibration.
В настоящее время снижение виброактивности при центробежном отжиме является одним из при-оритетных вопросов, стоящих перед разработчиками стиральных машин барабанного типа. Актуальность данной про-блемы обусловлена необходимостью обеспечения более высоких показателей надежности, безопасности и экономич-ности стиральных машин, а также снижения вредного воздействия вибрации и шума на человека.
Эффективным направлением снижения виброактивности стиральных машин является использование жид-костных автобалансирующих устройств (АБУ) — в частности, АБУ с вытесняемой жидкостью [1–4].
Вопросам исследования жидкостных АБУ, применяемых в стиральных машинах, посвящен ряд научных пуб-ликаций. При этом исследователи отмечают недостаточность имеющейся в настоящее время информации о дисба-лансных характеристиках отклика системы и стабильности работы устройства [5, 6].
1. Alekhin, S.N., et al. Stiral´naya mashina barabannogo tipa: patent 2516147 Ros. Federatsiya: C1D06F 37/00. [Drum-type washing machine.] Patent RF, no. 2516147, 2014 (in Russian).
2. Alekhin, S.N., et al. Stiral´naya mashina barabannogo tipa: patent 2469138 Ros. Federatsiya: C1D06F 39/00. [Drum-type washing machine.] Patent RF, no. 2469138, 2012 (in Russian).
3. Zheltushkin, L.S., Alekhin, S.N. Avtobalansirovochnoe ustroystvo zhidkostnogo tipa dlya stiral´nykh mashin s tsen-trobezhnym otzhimom. [Auto-balancing fluid-type device for washing machines with centrifugal spinning.] Vestnik Severo-Kavkazskogo gumanitarnogo instituta, 2013, no. 1 (5), pp. 166-170 (in Russian).
4. Alekhin, S.N, et al. Self-Balancing Equipment of Drum-Type Washing Machines. Young scientist USA, 2014, vol. 1, book 5, pp. 9-11.
5. Majewski, T. Fluid automatic balancer for a washing machine. Memorias del XVI congreso internacional anual de la SOMIM. Monterrey; Nuevo León; México, 2010, pp. 3-12.
6. Urbiola-Soto, L., Lopez-Parra , M. Liquid self-balancing device effects on flexible rotor stability. Shock and Vibration, 2013, vol. 20, iss. 1, pp. 109-121.
7. Alekhin, S.N., Zheltushkin, L.S., Alekhin, A.S. Issledovanie protsessa peremeshcheniya vnutrenney emkosti avto-balansiruyushchego ustroystva s vytesnyaemoy zhidkost´yu stiral´nykh mashin. [Research of process of relocation of internal capacity of the autobalacing device with the forced-out liquid of washing machines.] Technico-tehnologicheskie problemy servisa, 2014, no. 3 (29), pp. 32-37 (in Russian).
8. Alekhin, S.N., et al. Issledovanie protsessa peremeshcheniya vnutrenney emkosti avtobalansiruyushchego ustroystva s vytesnyaemoy zhidkost´yu stiral´nykh mashin. [Research of balances in liquid self-balancing device at maximum unbalanced force.] In the World of Scientific Discoveries, 2015, no. 8 (68), pp. 9-24 (in Russian).
9. Naberezhnykh, А.I., Sumzina, L.V. Bytovye stiral´nye mashiny. [Household washing machines.] Moscow: Izd-vo MGUS, 2000, 176 p. (in Russian).
10. Alekhin, S.N, et al. Formirovanie uravnoveshivayushchikh mass pri silovom smeshchenii vnutrenney emkosti avtobalansiruyushchego ustroystva stiral´noy mashiny. [Forming balance masses under power displacement of internal capaci-ty of self-balancing device of washing machine.] In the World of Scientific Discoveries, 2014, no. 6.1 (54), pp. 640-656 (in Russian).
11. Fetisov, I.V. Issledovanie sluchaynykh vozdeystviy na vibratsionnye kharakteristiki stiral´nykh mashin bara-bannogo tipa pri otzhime: dis. … kand. tekhn. nauk. [Research of random actions on vibration characteristics of the drum washing machine during the spin cycle: Cand.Sci. (Eng.) diss.] Shakhty, 2011, 199 p. (in Russian). 12. Alekhin, А.S. Issledovanie i vybor ratsional´nykh parametrov sistemy vibroizolyatsii stiral´nykh mashin s uchetom dinamicheskoy neuravnoveshennosti barabana : dis. ... kand. tekhn. nauk. [Research and selection of rational parameters of vibration isolation system of washing machines with dynamic drum unbalance: Cand.Sci. (Eng.) diss.] Shakhty, 2012, 184 p. (in Russian). 13. Makhov, D.P. Razrabotka i issledovanie sposoba snizheniya vibroaktivnosti stiral´nykh mashin barabannogo tipa pri otzhime: dis. … kand. tekhn. nauk. [Development and research of method of reducing vibroactivity of drum-type washing machine during the spin cycle: Cand.Sci. (Eng.) diss.] Shakhty, 2009, 200 p. (in Russian).
