RU174691U1 - ROTATION SIMULATOR - Google Patents

Abstract

The utility model relates to sports equipment and can be used to train athletes, in particular skaters, as well as in fitness centers and for entertainment at home. The technical result of the proposed solution is to expand the simulator's functionality by eliminating the effect of the engine braking on independent rotational movement of an athlete on a rotating platform. To achieve the claimed technical result in a rotation simulator, including we have the base 1, the rotation platform 2 and the engine 3, rigidly fixed to the base 1, and on the shaft of the engine 3 there is a drive pulley 4 connected via a belt drive 5 to the axis of rotation, which is connected to the platform 2, the transmission scheme of movement from the engine shaft to rotation platform. The drive pulley 4 is made in the form of a unidirectional rotation bearing, consisting of an inner 7 and an outer 8 rings, which are fastened together by a key connection 9, while the inner ring of the bearing is fixed to the motor shaft 3, and the outer ring is connected to a belt drive 5. Introduction to the design unidirectional rotation bearing simulator allows you to complicate and diversify training exercises during the training cycle, in particular to create free rotation, overcoming the inhibitory effect of electric rodvigatelya. 2 ill.

Description

The utility model relates to sports equipment and can be used to train athletes, in particular skaters, as well as in fitness centers and for entertainment at home.

A well-known training complex for the development of coordination of movements and vestibular stability in complex coordination sports (RF patent for the invention No. 2595595, publ. 08/27/2016). The complex includes a rotating simulator containing a frame from the base and a rotating platform, an electric motor with reverse movement and an electric motor control unit. The electric motor and control unit are mounted on a vertical structure, the motor is connected to a pulley with two electromagnetic couplings located on the same shaft of the rotation drive with two versatile overrunning couplings.

The design drawback is cumbersome, since a support bearing, two electromagnetic overrunning clutches, a belt drive pulley are placed on one axis.

The closest constructive solution for the proposed simulator can be considered a portable rotating simulator (RF patent for utility model No. 160003, publ. 02.27.2016). The simulator includes a rotating platform fixed in the bearing assembly, a base and a platform rotation motor connected to the rotation motor control unit. The rotating platform and base are made in the form of two identical disks concentrically articulated by the bearing assembly, and the electric motor is rigidly fixed to the base with the displacement of the electric motor shaft relative to the axis of the bearing assembly, the electric motor shaft being coupled to the rotating platform by a torque transmission mechanism.

The design drawback is the constant articulation of the engine and the rotating platform through a belt drive, which interferes with the free rotation of the platform, which limits the functionality of the simulator.

The technical result of the proposed solution is to expand the functionality of the simulator by eliminating the influence of the braking of the rotation engine on the independent rotational movements of an athlete located on a rotating platform.

To achieve the claimed technical result in a rotation simulator, including a base, a rotation platform and an electric motor rigidly fixed to the base, the drive pulley connected through the belt drive to the rotation axis, which is connected to the platform, is mounted on the motor shaft, the transmission scheme of movement from the motor shaft has been changed to the rotation platform. The drive pulley is made in the form of a unidirectional rotation bearing, consisting of inner and outer rings, which are fastened to each other by a key connection, while the inner ring of the bearing is fixed to the motor shaft, and the outer ring is connected to the belt drive.

The introduction of unidirectional rotation bearing into the design of the simulator makes it possible to complicate and diversify the training exercises during the training cycle, in particular, to create free rotation, overcoming the inhibitory effect of the electric motor.

The proposed simulator is illustrated by drawings: where are shown:

FIG. 1 is a structural diagram of a simulator,

FIG. 2 - drive pulley assembly with unidirectional rotation bearing.

The rotation simulator contains (Fig. 1) a base 1, a rotation platform 2 and an engine 3. The engine 3 is mounted on the base 1. On the shaft of the engine 3 there is a drive pulley 4 with a belt drive 5, which interacts with a driven pulley 6, rigidly connected to the platform 2 .

The drive pulley 4 is made in the form of a unidirectional rotation bearing (Fig. 2), which contains an inner ring 7 and an outer ring 8. Structurally, the inner ring 7 of the bearing is attached to the motor shaft, and the outer ring 8 is connected to a belt drive 5. For coupling the rings to each other a key connection 9 and two washers 10 are used, which are tightened by a lock nut 11 on the motor shaft 3. Thus, the motor shaft and the axis of rotation of the platform are spaced horizontally, but unlike the prototype, the mechanism received additional features due to Separation of the movement of the motor shaft and the rotating platform through the use of a unidirectional rotation bearing. It became possible to overtake the speed of rotation of the platform relative to the speed of rotation of the engine. The possibility of free rotation of the platform with the engine turned off also appeared.

The engine is powered by a power supply (not shown), and the rotation speed is controlled by an external regulator 12. For safety, the entire structure is protected by a casing (not shown).

The simulator is used as follows. When the electric motor is turned on, a torque is created on its shaft, which is transmitted to the axis of the platform, which begins to rotate with the athlete on it. This is an exercise on passive rotation. By changing the grouping of the body (changing the position of the arms and legs of the athlete), the athlete can independently create additional rotation - active rotation. At the same time, due to the presence of unidirectional rotation in the bearing circuit, it becomes possible to overtake the engine speed. This allows you to complicate and diversify training exercises, i.e. it becomes possible to create active rotation in addition to the engine without braking the rotation from the engine side. This improves the quality of training and improves athlete training.

In addition, the proposed simulator allows rotation even when the engine is off - the so-called free run-out, which also extends the simulator's functionality and expands the training capabilities.

Thus, the proposed simulator due to changes in the design scheme allows you to expand the functionality of the simulator, to diversify and complicate the training process and improve the quality of training an athlete.

Claims (1)

A rotation simulator including a base, a rotation platform and an electric motor, the engine is rigidly fixed to the base, a drive pulley is placed on the engine axis, connected via a belt drive to a rotation axis, which is connected to the platform, characterized in that the drive pulley is made in the form of a unidirectional rotation bearing, consisting of inner and outer rings, which are fastened together by a key connection, while the inner ring of the bearing is fixed to the motor shaft, and the outer ring is connected to the belt transmission.

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