RU208054U1 - Flywheel with variable moment of inertia - Google Patents

Abstract

The utility model relates to mechanical engineering and can be used in vehicle drives in order to reduce fuel consumption by recuperating braking energy. sectors are closely related to each other. The gear sectors are engaged with the central gear, inside which there are two potential energy storage devices in the form of torsion springs. reducing fuel consumption in the engine due to the accumulation of energy during regenerative braking and the subsequent use of the stored energy for starting and accelerating the vehicle.

Description

The utility model relates to mechanical engineering and can be used in vehicle drives in order to reduce fuel consumption by recuperating braking energy.

Known flywheel of variable moment of inertia (patent No. 2516883), containing a shaft on which a three-beam bracket is rigidly fixed, at the ends of which flywheel sectors with a gear mechanism for turning the flywheel sectors are rotatably fixed. The flywheel also contains a potential energy storage made in the form of a torsion spring.

The disadvantage of this flywheel is the low energy consumption of a single torsion spring, which does not allow accumulating a sufficient amount of potential energy of elastic deformation.

The technical task of the utility model is the creation of a flywheel with a variable moment of inertia, capable of accumulating in sufficient quantities the kinetic energy of the rotating masses and the potential energy of elastically deformed elements.

The technical result is to reduce fuel consumption in the engine due to the accumulation of energy during regenerative braking and the subsequent use of the accumulated energy for starting and accelerating the vehicle.

The technical problem is solved by the proposed flywheel with a variable moment of inertia (hereinafter referred to as the flywheel), which contains a shaft on which a three-beam bracket is rigidly fixed and a sleeve is installed using bearings with the ability to rotate around the shaft. In the cavity formed by the shaft and the sleeve there is a first potential energy storage made in the form of a torsion spring wound around the shaft, the ends of which are connected to the shaft and the sleeve. A central gear is mounted on the bushing by means of radial bearings with the ability to rotate around the bushing. In the cavity formed by the sleeve and the central gear, there is a second potential energy storage made in the form of a torsion spring wound around the sleeve, the ends of which are connected to the sleeve and the central gear. At the ends of the bracket, flywheel sectors and toothed sectors are fixed coaxially with the possibility of rotation, rigidly connected to each other by strips, and the toothed sectors are in mesh with the central gear. For periodic connection and disconnection of the flywheel shaft with the power take-off shaft, an electromagnetic disc friction clutch is provided.

The use of the proposed flywheel will reduce the fuel consumption in the engine due to the accumulation of energy during regenerative braking and the subsequent use of the accumulated energy for starting and accelerating the vehicle.

FIG. 1 shows the flywheel in a folded position. FIG. 2 shows a sectional view of the flywheel in a folded position. FIG. 3 shows the flywheel in an open position.

A flywheel with a variable moment of inertia contains a shaft 1, on which a three-beam bracket 2 is rigidly fixed and a bushing 4 is installed with the help of bearings 3 with the ability to rotate around a shaft 1. In the cavity formed by a shaft 1 and a bushing 4 there is a first potential energy storage made in the form of a spring torsion 5, wound around the shaft 1, the ends of which are connected to the shaft 1 and the bushing 4. A central gear 7 is installed on the bushing 4 by means of radial bearings 6 with the ability to rotate around the bushing 4. In the cavity formed by the bushing 4 and the central gear 7, there is a second storage potential energy, made in the form of a torsion spring 8, wound around the sleeve 4, the ends of which are connected to the sleeve

4 and the central gear 7. At the ends of the bracket 2, flywheel sectors 9 and gear sectors 10 are fixed coaxially with the possibility of rotation, rigidly connected to each other by strips 11, and the gear sectors 10 are meshed with the central gear 7. For periodic connection and disconnection of the shaft 1 an electromagnetic disc friction clutch 13 is provided with the power take-off shaft 12.

In a stopped position or at a low speed, the flywheel is in a folded position (Figs. 1, 2): the flywheel sectors 5 are pressed to the center of the flywheel by the force of torsion springs 5 and 8 by engaging the gear sectors 10 with the central gear 7. During regenerative braking, an electromagnetic clutch is activated 13, and rotation from the power take-off shaft 12 is transmitted to the flywheel shaft 1. With an increase in the speed of rotation of the shaft 1, the flywheel sectors 9, due to the action of centrifugal forces on them, rotate around their axes, overcoming the force of the torsion springs 5 and 8 through the engagement of the gear sectors 10 and gears 7. The flywheel goes into the open position (Fig. 3), its moment inertia increases, while participating in braking the vehicle and storing energy. Moreover, not only the kinetic energy of the rotating flywheel sectors 9 is accumulated, but also the potential energy of the elastically deformed torsion springs 5 and 8. At the end of the braking cycle, the electromagnetic clutch 13 is turned off, and the flywheel continues to rotate freely in the open position.

Subsequently, when it is necessary to continue driving, the accumulated energy of the flywheel is used for starting and accelerating the vehicle. To do this, the electromagnetic clutch 13 is turned on again, through which rotation from the shaft 1 is transmitted to the power take-off shaft 12, and, giving off energy, the flywheel tends to slow down, which leads to a decrease in the centrifugal forces acting on the flywheel sectors 9 and to their folding due to the action of the springs torsion 5 and 8. In this case, the flywheel gives up the accumulated kinetic energy of the rotating flywheel sectors 9 and the potential energy of the elastically deformed torsion springs 5 and 8. When the flywheel sectors 9 are fully folded to the center of the flywheel, the electromagnetic clutch 13 is turned off and the flywheel is ready for operation again.

Claims (1)

A flywheel with a variable moment of inertia, containing a shaft on which a three-beam bracket is rigidly fixed, characterized in that a sleeve is mounted on the shaft with the help of bearings with the ability to rotate around the shaft, in the cavity formed by the shaft and the sleeve there is a first potential energy storage made in the form of a spring twisted around the shaft, the ends of which are connected to the shaft and the bushing, a central gear is mounted on the bushing through radial bearings with the ability to rotate around the bushing, in the cavity formed by the bushing and the central gear, a second potential energy storage device is located, made in the form of a torsion spring, wound around the sleeve, the ends of which are connected to the sleeve and the central gear, at the ends of the bracket, flywheel sectors and toothed sectors are fixed coaxially with the possibility of rotation, rigidly connected to each other, and the toothed sectors are in mesh with the central gear.

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