RU2008544C1 - Variable speed drive - Google Patents

Abstract

FIELD: mechanical engineering. SUBSTANCE: variable speed drive comprises input 1 and output 2 shafts, hollow driving conical friction member 3 mounted on input shaft 1, at least one driven conical friction member 4 arranged with a radial clearance along generatrix relative to driving conical member 3, magnet installed in the latter with a provision for axial movement, and ferromagnetic liquid contained in gap. At least one additional driven conical friction member 4 is installed with a radial clearance along generatrix relative to driving conical friction member 3 in such a manner that the latter is disposed between driven conical friction members. Output wheel of multiple-flow wear transmission is installed on output shaft 2 while input wheels are meshed by means of corresponding driven conical friction members. EFFECT: improved design. 2 cl, 4 dwg

Description

 The invention relates to mechanical engineering and is intended for smoothly controlling the speed of rotation of the driven shaft.

 Known variator containing two friction conical pulleys on parallel shafts and an intermediate element of elastic material [1].

 A variator is also known, comprising two friction conical elements mounted in a housing on parallel shafts, and an intermediate element located between them. The variator is equipped with a magnet mounted on parallel shafts with the possibility of axial movement in the cavities of the conical elements. The intermediate element is a ferromagnetic fluid [2].

 The main disadvantage of the variator is the relatively low load capacity due to the relatively small working surface of the intermediate element.

 The aim of the invention is to increase the load capacity of the variator.

 This goal is achieved by the fact that the known variator containing the input and output shafts, a hollow driving conical friction element mounted on the input shaft, at least one driven conical friction element mounted with a radial clearance along the generatrix relative to the leading conical friction element, mounted in the cavity of the latter with the possibility of axial movement of the magnet, and the ferromagnetic fluid placed in the gap is equipped with at least one additional driven conical friction lementom mounted with radial clearance relative to the master along a generator of the conical friction element so that the latter is disposed between the driven bevel friction elements and the threaded gear, an output wheel which is mounted on the output shaft and the input wheel associated with respective driven bevel friction elements. Input and output shafts are aligned.

 This embodiment of the variator significantly increases its load capacity. This is the achieved positive effect, on the basis of which the design differences of the claimed variator should be considered significant.

 In FIG. 1 shows the proposed variator, a longitudinal section; in FIG. 2 is a section AA in FIG. 1; in FIG. 3 is a section BB in FIG. 1; in FIG. 4 is a section BB of FIG. 1.

 The variator contains input 1 and output 2 shafts, drive 3 and driven 4 friction elements, magnet 5, an intermediate element 6 of ferromagnetic fluid 7, poured into the cavity of the housing 8. Magnet 5 is made, for example, in the form of a cylindrical washer, in the hole of which is on bearings mounted rod 9 with a spline outer surface and a threaded hole. The rod 9 is installed in the spline hole of the stationary stand 10 inside the housing 8. A rod 11 is screwed into the threaded hole of the rod 9, at the end of which a bevel gear 12 is fixed, coupled with another bevel gear 13 on the shaft 14. The rod 11 and the shaft 14 are also mounted on the strut 10 in the respective angular contact bearings 15 and 16. The driven friction elements 4 are mounted on the intermediate shafts 17 mounted in the bearings 18 and the bearing gears 19, engaged with the gear wheel 20 in the end part of the shaft 2.

 With manual control of the variator, a handwheel 21 and a latch (not shown) are installed at the end of the shaft 14.

 Alternatively, instead of a bevel gear (12-13), a self-braking worm gear can be used, and the wheel 20 is made with internal gearing (in contrast to the one shown in Fig. 1).

 To change the ferromagnetic fluid in the case of the variator, holes with valves 22 and 23 (or plugs) are provided.

 The variator works as follows.

 The torque from the shaft 1 to the shaft 2 is transmitted through the conical friction elements 3 and 4, the intermediate element 6, gears 19 and the gear wheel 20. The intermediate element 5 can change its position depending on the position of the magnet 5, when moving along the axis of the friction elements changes gear ratio of the variator. The magnet 5 is moved by a helical gear (9-11, the screw of which (rod 11) is rotated by the handwheel 21 through the shaft 14 and the bevel gear (12-13).

 The use of the invention allows to expand the technical capabilities of mechanical engineering. (56) 1. Kozhevnikov S.M. Elements of mechanisms. M.: Oborongiz, 1950, FIG. 1251.

 2. USSR author's certificate N 1193338, cl. F 16 H 15/01, 1984.

Claims (2)

 1. VARIATOR containing input and output shafts, a hollow driving conical friction element mounted on the input shaft, at least one driven conical friction element mounted with a radial clearance along the generatrix relative to the leading conical friction element, mounted in the cavity of the latter with the possibility of axial movement of the magnet and a ferromagnetic fluid placed in the gap, characterized in that, in order to increase the load capacity, the variator is equipped with at least one additional a driven conical friction element mounted with a radial clearance along the generatrix relative to the leading conical friction element so that the latter is located between the driven conical friction elements, and a multi-threaded gear transmission, the output wheel of which is mounted on the output shaft, and the input wheels are connected to the corresponding driven conical friction elements.  2. The variator according to claim 1, characterized in that the input and output shafts are aligned.

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