Конструювання, виробництво та експлуатація сільськогосподарських машин. Випуск 47. Ч. 2. - 2017
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Item До визначення швидкості ковзання та зусилль, які діють в зачепленні черв’ячної передачі(ЦНТУ, 2017) Невдаха, Ю. А.; Дубовик, В. О.; Невдаха, А. Ю.; Пукалов, В. В.; Nevdaha, Y.; Dubovik, V.; Nevdaha, А.; Pukalov, V.В статті розглянута величина швидкості ковзання і її напрям відносно лінії дотикання черв’яка і черв’ячного колеса, визначені швидкості ковзання та зусилля, які діють в зачепленні. The purpose of the article is to investigate ways to increase the durability and tractive ability of worm gears. Improve the durability of worm gears by improving the working environment, as well as by applying an oil wedge. One of the ways to increase the pressure in the oil wedge, as well as increasing the loading capacity of the transmission is to change the geometry of the clutch. The article considers the value of the slip speed and its direction relative to the line of contact of the worm and worm wheel. The sliding speeds and forces that are in contact are determined. The peculiarity of a worm gear is slipping along the teeth. The magnitude of the slip velocity and its direction relative to the line of contact between the two bodies moving relative to each other, as well as the shape of the tangential surfaces, largely determine the hydrodynamic conditions of the engagement and, consequently, affect the performance of the transmission. Investigating the speed of sliding in worm gears it was found that the speed of movement of the contact line relative to the tooth of the worm wheel was small compared with the speed of the worm worm. The values of the angles formed by contact lines with directions for different points of the worm vary in a wide range. It was established that conditions for the formation of an oil wedge deteriorate with a decrease in the angle of recovery of a worm turn.Item Дослідження складових опору ґрунту при роботі щіткових пристроїв(ЦНТУ, 2017) Войтік, А. В.; Головатюк, А. А.; Гнатюк, М. Г.; Voytik, А.; Golovatyuk, А.; Gnatyuk, M.В статті розглянуто силову взаємодію прутка ворсу циліндричної щітки з ґрунтом в процесі видалення останнього з валків, що вкривають кореневу систему маточних рослин. Встановлено, що на енергоємність процесу будуть впливати сили в’язкості ґрунту, статичного опору його частинок та опору на відкидання ґрунту з валка. Також на опір впливають сили, що викликані переміщенням ущільненого ядра та сили тертя призми волочіння по поверхні прутка та ґрунтового валка. The article is devoted to the problem of the disclosure of the root system of mother plants with brush working parts. When working brushes on their pile rods there are resistance forces that require certain energy costs. By selecting rational kinematic parameters, it is possible to minimize energy costs for work. In this work the position of the pile rod in the working phase is analyzed and the forces acting on it are determined. The main resistance force is directed opposite to the absolute velocity vector and includes three components. Firstly, these forces of resistance are caused by the viscosity of the soil, taking into account its plasticity and deformation. The force of the static resistor of the displacement of particles takes into account the properties of the soil as a friable medium simultaneously with plastic properties. Also, the force to reject soil particles is determined. It has been established that in addition to these forces, resistance is caused by the displacement of the core of the seal under the working rod and the frictional forces when driving the prisms of drawing on the surfaces of both the rod itself and the ground roll. The dependence of the resistance strength on the movement of the rod in the soil from the basic parameters of the brush has been determined, and it has been shown that there is a minimum of function within the limits of the change in the velocity of the pile rods from 3 to 6 m / s, when the force takes the minimum values up to 0.3 N per rod.