SU875130A1 - Device with variable inertia moment - Google Patents

Description

(54) DEVICE WITH VARIABLE MOMENT OF INERTIA

Claims (2)

The invention relates to mechanical engineering, namely to inertial energy accumulators, and can be used as a device with a variable moment of inertia. A known flywheel with an interchangeable pulse of inertia, in an inertial vibrator, containing a clutch element mounted on the shaft and in contact with the flywheel C1. The closest to the present invention is a device with a variable moment of inertia, which contains a flywheel placed on a shaft in a videopolis body filled with liquid, the housing is rigidly fixed on the shaft, and is radially arranged in the form of pistons with radial displacement 2 A disadvantage of the known devices is the high time constant of regulation of the moment of inertia in conjunction with the design features of these devices. The purpose of the invention is to reduce the constant time of regulation of the moment of inertia. The goal is achieved by the fact that in a device with a variable moment of inertia, containing a hosted. A shaft filled with liquid, a flywheel, an insertion case filled with a liquid, a case mounted on a shaft with the possibility of assembly, a fluid electrorheological, and a flywheel equipped with conductor located in the case, made of conductive material and electrically insulated from one another by two conical disks conical surfaces and rigidly connected to the shaft. FIG. 1 is a schematic diagram of the device; in fig. 2 is a graph of viscosity U of an electrorheological fluid versus voltage E of an electric field; FIG. Profile of conical flywheel disks; Fig. 4 is a graph of viscosity and electrheo-ray fluid versus electric voltage V and radius R of the flywheel discs; in fig. 5 - dependence of the intensity E of the electric field -from the radius R of the flywheel disks. The device contains a flywheel placed on the shaft 1, comprising a hollow Kopnyt 2, filled with liquid 3, the housing is mounted on the shaft 1 rotatably on bearings 4, liquid 3 is electrorheological, and the flywheel is fitted with dimensions of conductive brushed material and electrically insulating one from the other with the help of a trunking conductor gasket 5 by two coherent disks 6 and 7, tapered surfaces 8 and 9 facing each other and sisterly connected to the shaft 1. The disks 6 and 7 of the flywheel are connected via contacts 1.0 and 11 to the source of electrical voltage 12. The device operates as follows. The electrorheological fluid 3 has the property of changing its viscosity Vj when a certain value E of the electric field is reached (Figs. 2-5). The effective viscosity of an electrorheological fluid 3 grows approximately in a parabolic dependence on the strength E of the electric field until a certain value of the strength of 4E.p. Electric field is reached, when the effective viscosity f ceases to depend on the strength E of the electrical field and reaches full hardening of the electrorheological liquids 3 (Fig. 2). When a certain value of the electric voltage V is applied by contacts 10 and II, a tension is created between the conic surfaces 8 and 9 of the disks 6 and 7 E electric field and liquid 3, located in the space between disks 6 and 7, are made conically molded; the strength of the electric field E is not the same and is greatest at the point where the distance between surfaces 8 and 9 is the smallest, t, e , closer to the center of the keys b and 7 of the flywheel (Fig, 5). Thus, the electrorheological liquid 3 primarily hardens closer to the center of the disks 6 and 04 7 and depends on the radius R of the disks 6 and 7 (Fig. 3). When a certain value of electrical voltage is reached (Fig. 4), full hardening is achieved; electrorheological fluid. The moment of inertia depends on the magnitude of the electric voltage E. Thus, it is possible to change the moment of inertia of the device. When the voltage V increases, the moment of inertia increases until electrorheological fluid 3 located between the conical surfaces 8 and 9 of the disks 6 and 7 of the flywheel completely solidifies and then the moment of inertia f becomes constant. The electrorheological fluid 3, solidified under the influence of the electric field strength E, quickly becomes liquid when this field disappears. As a result, the electric field, which has hardened under the influence of the intensity E, turns into a liquid again towards the center of the disks 6 and 7. of the flywheel. When the electrical voltage V decreases, the inertia moment decreases. The constant of the solidification time of the liquid, and thus the constant of the regulation time of the moment of inertia, is fractions of m / s, which is 4 times less than in the known device. Claims A device with a variable moment of inertia, comprising a flywheel placed on a shaft, comprising a hollow body filled with a liquid, characterized in that, in order to reduce the time required to adjust the moment of inertia, the body is mounted on a shaft with the possibility of rotating a liquid-electrorheological and the flywheel is fitted with two conical disks facing each other, made of a conductive material and electrically isolated from one another, and conical surfaces facing each other strictly connected with the shaft. Sources of information taken into account in the examination 1, USSR Copyright Certificate 242015, cl. B 06 B 1/16, 1968. 2. US patent 3248967, class, F 16 F 15/30, 1971 prototype). % ig. Fig.Z fl FIG.