In the article research related to the increasing in the scope of application of additive technologies in the construction of machines for the production of gears with involute and sinusoidal profile from polymeric materials was presented. The designed original research stand and with its use carried out a series of preliminary fatigue tests of the obtained polymer gears with an involute and sinusoidal profile was show. The tested gears were obtained in the technology of rapid prototyping by the FFF (Fused Filament Fabrication) method from polymer composites obtained in the form of an ABS (acrylonitrile/butadiene/styrene) -based filament. Based on the results obtained, it was noticed that the temperature in the meshing zone of the gears with involute profiles is higher than for sinusoidal profiles, regardless of the type of composite from which the gears were made. It should also be noted that in the range of nominal load, the sound intensity level of the meshing zone is also lower for gears with a sinusoidal profile than for gears with an involute profile. Based on the tests carried out, an increase in sound intensity was noticed in the case of gears obtained from selected composites (Table 2) compared to the gear obtained from unfilled ABS. However, in the case of gears obtained from the tested composite materials, we observe a decrease in the gear operating temperature (Table 2). The most favorable results of these tests were obtained for gears with a sinusoidal profile obtained from ABS + P2 composite, which show the lowest operating temperature of the gear. It should also be mentioned that slightly worse results were obtained for involute gears.
Purpose -The purpose of this paper is to determine the instantaneous contact area in a gearbox using rapid prototyping. Design/methodology/approach -The determination of the contact area utilizes one of the RP techniques, i.e. stereolithography. Stereolithography enables the making of gears with complex profiles, which are difficult to obtain by means of other machining methods. A model of a bevel gearbox with Gleason spiral generated modify roll (Gleason SGM) gears with circular-arc profiles of teeth is applied as an example for testing. A prototype of the gearbox was made using SLA 250 apparatus. Findings -Correct mating of gears and their kinematical precision depend on the shape and size of the instantaneous contact area, as well as changes during the turning of gears. Contact between gear surfaces of a geometrically ideal gearbox occurs at a point or line, but, because of a deformability of mating flanks teeth, in reality it is always a certain surface. This paper presents research on the instantaneous contact area with area on the surface of a flank tooth, which is in contact with the mating surface of another tooth at a specific moment. Originality/value -The described method in the paper enables a dynamic determination of the mating area gearbox. Existing experimental methods enable only a static observation of the mating area. A stand test was built and enables an exact meshing of mating gears. Gears were made of transparent material, SL-5170, which enables observation of the instantaneous contact area.
Przedstawiono matematyczny opis powierzchni boku ślimacz-nicy przekładni ślimakowej globoidalnej. Pokazano układ kinematyczny kształtowania boku zęba ślimacznicy oraz wykorzystano matematyczny opis powierzchni bocznej ślimaka globoidalnego. SŁOWA KLUCZOWE: przekładnia ślimakowa globoidalna, śli-mak globoidalny, ślimacznicaPresented is a mathematical description of tooth flank surface of the wormwheel in globoid worm gear. The kinematic system of tooth formation was performed. The mathematical description of tooth flank of globoid worm was used.
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