RU87091U1 - Inertial Trainer - Google Patents

Abstract

1. Inertial simulator containing a housing driven in rotation from an engine with a drive providing a variable speed of rotation, characterized in that the housing is made in the form of the lower part of the torus with a platform in the center and mounted on supporting wheels, at least one of which is connected with the drive of its rotation, mounted on the supporting surface is an elevator shaft passed through the center of the casing platform with doorways for lifting the user on the elevator to the casing platform, and on the elevator shaft with the possibility of rotation from the drive Fitting eversnoy fixed carousel which is adapted to move the carriages in a radial direction relative to the sling body intended for attachment to the user. ! 2. The inertial simulator according to claim 1, characterized in that the housing is configured to fill with water and flow through collectors connected by pipes, one of which is mounted in the upper part of the housing wall along the perimeter of the latter, and the other at the site. ! 3. The inertial simulator according to claim 1, characterized in that a ladder is mounted on the outer or inner surface of the shaft of the elevator shaft for lifting the user along it to the platform of the housing. ! 4. The inertial simulator according to claim 1, characterized in that the inner surface of the housing is made with a hard coating. ! 5. The inertial simulator according to claim 1, characterized in that the drive is made reversible.

Description

The utility model relates to the field of sports, entertainment and attractions. The simulator allows you to simulate situations in which a person experiences physical exertion de facto and is forced to respond to them, performing the same actions as in a real workout.

So there is a known method of training athletes to develop coordination of movements when performing complex human movements in space, carried out, for example, on a trampoline - a grid with rubber shock absorbers designed to perform jumps, somersaults and various turns (TSB, M., "Soviet Encyclopedia", 1970 , Vol. 3, v. 3, p. 124).

This method of training allows you to practice the technique of coordinating the movement of the body when it is moving in space, but it does not allow creating sufficient physical stress on the human body when it is moving in space.

There are also various simulators that allow you to create physical exertion on various muscle groups, but do not allow training to coordinate movement (PCT No. 94/27678, publ. 08.12.94).

A method of training coordination of movement, which consists in moving the body in space with a periodic change in its position with power loading, which allows you to develop the skills of positional stability of an athlete due to the formation of an athlete's reaction to an external load that changes in direction and magnitude, aimed at removing it from a stable equilibrium position ( EP 0488436, published 07.11.91), This method allows you to work out some movements that combine coordination and development of skills to maintain positional stability athlete.

The disadvantage of this method of training is the limited ability to practice coordination of movement while creating the appropriate physical load on various muscle groups. Another disadvantage of this known method is that it is based on the development of the athlete’s skills to maintain positional stability, which are the result of his physical development, the state of the vestibular apparatus and the ability to respond to changing conditions. Thus, this method is more focused on the development of the athlete's natural data than on the formation of new abilities.

Current trends in the development of game sports, aimed at increasing speeds and physical activity, require the athlete to think faster: orienteering in extreme competitive situations, taking into account the properties of the playing field coverage; the execution of the correct techniques in the shortest periods of time, while maintaining positional stability regardless of the type, strength and direction of the force impact, i.e. high automatism of actions in conditions of statokinetic interference is needed. This requires expanding the athlete’s functional capabilities, especially increasing his statokipetic noise immunity (positional stability), as well as increasing the stability and endurance of the vestibular analyzer, which plays a leading role in the implementation of these tasks.

Closest to the present invention is a device for training coordination of movement for the development of positional stability of an athlete to external influence, which consists in the formation of a response of an athlete to an external load that is variable in direction and magnitude, aimed at removing it from a position of stable equilibrium , publ. 11/23/1992).

A known training method is implemented using a rotating platform, which receives an adjustable rotational movement from the electric drive. In this case, the tilt angle of the platform can be changed by a special device. The athlete placed on the platform due to its larger diameter can perform various techniques during its rotation. It can be a shot on goal, a throw to the basket, etc., i.e. precision target techniques, as well as complex coordination techniques in gymnastics, figure skating and other sports. Complex repetitive motor skills are formed through repeated repetitions of techniques along with the development of statokinetic noise immunity in athletes.

The disadvantage of this device is that in the framework of training, real conditions cannot be achieved in which the athlete will have to perform certain techniques worked out on the platform. A feature of this method is that an athlete located on the platform, depending on its position from the geometric center, falls under the influence of inertial influences of various sizes. Due to the adaptability of the awn, after some time, the athlete begins to navigate on the platform and knows in advance on which of his distance from the center he will be exerted in advance of the expected external force. This method organizes the development of the vestibular analyzer well, but helps to get used to predetermined conditions.

For such game sports as American football, wrestling or other types of martial arts, the endurance of the vestibular analyzer and maintaining positional stability regardless of environmental conditions, time and magnitude of force are most important. Thus, for the development of these components in an athlete, the training conditions should be as close as possible to real actions. Since the use of mechanical training devices, due to their designs, does not allow developing an algorithm for influencing an athlete that is adequate to real conditions, it seems advisable to change the conditions of training. The change in conditions consists in the fact that training should be a set of actions aimed at the formation of power supporting structures, a certain position of which organizes the athlete's high positional stability to external influence.

The technical result that can be obtained by implementing the proposed device is to increase the effectiveness of training by creating an effective, fairly simple training device that develops coordination of movement and statokinetic noise immunity of an athlete to external force exposure in real conditions that repeat the conditions of a sports competition. The technical result also consists in ease of use and safety when climbing and descending.

1. The specified technical result is achieved by the fact that the inertial simulator containing the housing, driven into rotation from the engine with a drive that provides a variable speed of rotation, characterized in that the housing is made in the form of the lower part of the torus with a platform in the center and mounted on the support wheels, at least one of which is associated with its rotation drive, an elevator shaft with doorways mounted through the center of the casing platform is mounted on the supporting surface for lifting the user on the elevator to the casing platform, and The carriage is fixed to the elevator shaft with the possibility of rotation from the drive reverse installation, which is made with carriages of movement in the radial direction relative to the body of the slings intended for attachment to the user.

The housing can be made with the possibility of filling with water and its overflow through collectors connected by pipes, one of which is mounted in the upper part of the housing wall around the perimeter of the latter, and the other at the site.

On the outer or inner surface of the barrel of the elevator shaft, a ladder can be fixed for lifting the user along it to the platform of the body.

The inner surface of the housing can be made with a hard coating,

The drive can be made reversible.

These features are significant and interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

The present utility model is illustrated by the specific example shown in FIG. 1 — an inertial type simulator device is presented.

According to this utility model, an inertial simulator is considered, comprising a housing driven into rotation by an engine with a drive providing variable rotation speed and reversal. The casing is made in the form of the lower part of the torus with the platform in the center and mounted on the support wheels, at least one of which is connected with the drive of its rotation; on the supporting surface there is mounted an elevator box with doorways for passing the user on the elevator to the platform case and with a ladder mounted on the outer surface of the shaft of the shaft, also designed to climb to the site. A carousel is rotationally mounted on the elevator shaft, which is made with carriages moving in the radial direction relative to the body of the slings intended for attachment to the user, while the body is made with the possibility of filling with water and flowing through collectors connected by pipes, one of which is mounted in the upper part the walls of the body around the perimeter of the latter, and the other at the site.

Below is an example of the execution of such an inertial simulator.

The inertial simulator (Fig. 1) is a centrifuge-type device consisting of a housing 1 rotated around a vertical central axis by means of at least one driving wheel 2 mounted in a system of driven support wheels 3 mounted under the housing. The housing is supported by the outer surface on these wheels and when at least one driving wheel 2 rotates due to the contact of the latter with the housing 1, the rotation is transmitted from the driving wheel to the housing 1. The driving wheel 2 with its axis 4 through a variator 5 and a reverse 6, allowing rotation of the housing 1 with a variable speed and in opposite directions, connected to the drive motor 7. The simulator housing 1 is supported through a system of driving 2 wheels and driven 3 wheels located around the circumference of the supports 8. In the center of the housing 1 simulator The fixed trunk of the elevator shaft 9 with doorways 10, to which the platform 11 is mounted at a certain height, is mounted on the top, and a carousel 12 is mounted rotatably at the very top of the elevator shaft of the shaft 9, along which carriages 13 regulating the length move in the radial direction relative to the housing 1 and the location of the sling 14 carrying the attachment element to the user. The body of the simulator 1 is the lower part of the torus, can be made of variable cross-section. The body cavity is filled with water. The water mirror in the stationary position is indicated by pos. 15. When the simulator rotates, water is distributed over a toroidal surface. The water mirror in dynamics - pos. 16. Along the perimeter of the housing 1, in its upper part is a collector 17 for collecting excess water. Around the site 11, a collector 18 with nozzles is located around the perimeter, which supplies water to the torus cavity. The collectors 17 and 18 are interconnected by overflow pipes 19, which are located not along the meridians, but in a spiral both to one and the other side, which allows for natural flow of water between communicating collectors 17 and 18 due to the karyolis inertia. This water circulation system includes a water treatment system 20, and, if necessary, a pump unit and a water heating device. The carriage 13 occupies the “Y” position in the unloaded form, and under the weight of the athlete occupies the maximum “X” position.

The carousel 12 is mounted on the shaft of the shaft with the possibility of rotation from the drive reverse installation 21 (the drives of the body and carousel are unconnected and work in standalone modes), and on the outer or on the inner (not shown) surface of the shaft of the shaft is fixed (mounted) a ladder 22 that provides lift users to the site (similarly - descent). The presence of a ladder greatly facilitates the descent and ascent for users and is a safe component for evacuating users in case of disruption of the elevator.

The main idea of the simulator is to create autovisual and muscle loads on the athlete, which is achieved when the simulator body moves in a circle, when the inertia force acts on the body. The main task is the creation of a "centrifugal force", which by its action causes a physical sensation of movement on the crest of the sea "standing wave" for professionals of surfers, kitesurfing, wakeboarding.

If you give the rotating platform such a curvature that at a certain speed its surface is at each point perpendicular to the resulting (resultant forces), then the person will feel at all its points, as on a horizontal plane. If you pour water on such a surface, called a paraboloid, then it spreads in an even layer.

Consider figure 1 three characteristic points of the body of the simulator, rotating in the likeness of a vertical centrifuge.

At point "A" the effect of sliding down is ensured, since the weight force in the composition of the resulting forces is dominant. At point "B" the effect of sliding to the periphery and down is ensured. Between them, the boundary point "B", where the resultant force is perpendicular to the surface of the housing 1, where the effect of being on a horizontal surface appears.

The case 1 of the simulator, filled with a certain volume of water, simulates the crest of the "standing wave" in the form of a crescent month during rotation. The rider is forced to take actions: muscular efforts to lay bends, inclinations to fix the center of gravity of the body in space, etc., as a reaction to the conditions created by the simulator, simulating the selected environment. The simulator’s work is based on the presence of rotation inertia forces, which create a field of centrifugal forces, which, due to the selected housing configuration, gives the water surface the required curvature, and the carousel sling rod replaces the boat and kite thrust.

The inner surface of the simulator case may be made with a hard coating (not shown in the drawing).

Claims (5)

1. Inertial simulator containing a housing driven in rotation from an engine with a drive providing a variable speed of rotation, characterized in that the housing is made in the form of the lower part of the torus with a platform in the center and mounted on supporting wheels, at least one of which is connected with the drive of its rotation, mounted on the supporting surface is an elevator shaft passed through the center of the casing platform with doorways for lifting the user on the elevator to the casing platform, and on the elevator shaft with the possibility of rotation from the drive Fitting eversnoy fixed carousel which is adapted to move the carriages in a radial direction relative to the sling body intended for attachment to the user. 2. The inertial simulator according to claim 1, characterized in that the housing is configured to fill with water and flow through collectors connected by pipes, one of which is mounted in the upper part of the housing wall along the perimeter of the latter, and the other at the site. 3. The inertial simulator according to claim 1, characterized in that a ladder is mounted on the outer or inner surface of the shaft of the elevator shaft for lifting the user along it to the platform of the housing. 4. The inertial simulator according to claim 1, characterized in that the inner surface of the housing is made with a hard coating. 5. The inertial simulator according to claim 1, characterized in that the drive is made reversible.