RU94472U1 - FIGURIST SIMULATOR - Google Patents

Abstract

 1. A skater simulator comprising a platform mounted in a bearing, characterized in that a platform rotation motor, an overrunning clutch and an engine speed control unit are included in the composition, wherein the engine speed control unit is connected to the rotation engine. ! 2. The device according to claim 1, characterized in that it includes a skater body suspension system mounted on the cable of the block mechanism, while the axis of rotation of the platform is located along the line of tension of the cable. ! 3. The device according to claim 1, characterized in that it includes a podium, inside and in the center of which with a gap relative to the surface of the podium there is a platform so that the surface of the podium and the surface of the platform coincide in height relative to the base. ! 4. The device according to claim 1, characterized in that it is installed on the surface of the ice rink with artificial ice. ! 5. The device according to claim 1, characterized in that it is made with the possibility of changing the height of the platform relative to the base. ! 6. The device according to claim 1, characterized in that it is configured to tilt the platform relative to the base. ! 7. The device according to claim 1, characterized in that the platform mounted in the bearing, the freewheel and the platform rotation motor are integrated in the construction of the artificial ice rink. ! 8. The device according to claims 1 and 2, characterized in that the surface of the podium is provided with a coating of synthetic ice.

Description

The utility model relates to the field of devices for training skaters in complex movements and rotations in jumps.

Known devices for training skaters, made in the form of a lounge on which skaters practice jumping, see A. Mishin “Jumping in Figure Skating" FiS, M 1976

Also known is the simulator - the disc "Grace", which represents the platform on which the athlete becomes and on which he can rotate. At the same time, the rotation of the platform is given due to the muscular strength of the athlete. The disc manufacturer is Azuni, Taiwan. This simulator is selected as a prototype of a utility model.

The disadvantage of the prototype is the inability to achieve due to the muscles of the athlete a sufficiently high rotation speed at which it is desirable to develop the skill of performing fast complex coordination movements of the skater.

The objective of the utility model is to create a simulator in which the achievement of a high rotation speed becomes possible.

According to the utility model, this goal is achieved by the fact that a rotation motor, an overrunning clutch and an engine rotation speed control unit connected to the rotation engine are included in the simulator.

The essence of the utility model is shown in Figures 1-7.

Figures 1-7 indicate:

1 - engine with gear

2 - base

3 - bearing

4 - platform

5 - freewheel

6 - engine speed control unit

7 - skater

8 - crossbar

9 - slings

10 - straps

11 - safety belt

12 - bearing

13 - cable

14 - block

15 - upper base

16 - line tension cable

17 - axis of rotation of the platform

18 - coach

19 - podium

20 - clearance

21 - surface of the podium

22 - platform surface

23 - surface of the ice rink with artificial ice

24 - design of the ice rink with artificial ice

25 - plane

26 - synthetic ice podium cover

The skater's simulator is shown in Figures 1-8.

Figure 1 shows a skater simulator containing an engine with a gearbox 1 mounted on a base 2, for example, on the floor of a room. On the axis of the gearbox of the engine 2 in the bearing 3, a platform 4 with an overrunning clutch 5 is installed. The simulator includes an engine speed control unit 6 connected to the engine 1.

Skater 7 is mounted on platform 4.

Figure 2 shows the skater simulator, which introduced the skater's body suspension system 7, consisting of a crossbar 8 with slings 9, straps 10, a safety belt 11. The straps 10 are attached to the safety belt 11, and the straps 9 are fixed to the straps 10. The suspension system also includes a bearing 12, through which the crossbar 8 is connected to the cable 13 and the block 14, mounted on the upper base 15, for example, on the ceiling of the room. A cable 13 is thrown through the block 14. The tension line 16 of the cable 13 coincides with the axis of rotation of the platform 17.

The skater 7 is mounted on the platform 4 and mounted using a suspension system on the cable 13. The free end of the cable 6 is in the hands of the trainer 18.

Figure 3 shows the skater’s simulator, which includes the podium 19. Inside and in the center of the podium 19 with a gap 20 relative to the surface of the podium 21, platform 4 is located so that the surface of the podium 19 and the surface 22 of platform 4 coincide in height relative to the base 2.

Figure 4 shows the skater simulator mounted on the surface of the artificial ice rink 23.

Figure 5 shows the skater's simulator with the ability to change the height H of the platform 4 relative to the base 2. The value of H is variable.

Figure 6 shows the skater's simulator with the possibility of turning the platform 4 relative to the plane of the base 2 by an angle α.

Figure 7 shows the construction of the ice rink 24, in which the platform 4 mounted in the bearing 3, the overrunning clutch 5 and the engine of rotation of the platform 1 are mounted. In Fig. 7, the surface of the platform 22 and the surface of the ice rink with artificial ice 23 are located in the same plane 25.

Figure 8 shows the skater's simulator, in which the surface of the podium 21 is provided with a coating of synthetic ice 26.

The simulator shown in Fig. 1 is as follows. The skater without skates becomes on the platform 4. Then the trainer turns on the engine 1 and, with the help of the speed control unit of the engine 6, starts accelerating the platform 4 together with the skater 7. When the required angular speed ω _{bp is} reached _. rotation of the platform 4, the engine 1 is turned off and the platform 4 due to the use of overrunning clutch 5 begins to rotate on the coast. In the process of rotation of the platform, the skater performs various training movements of the body links - arms, legs, torso. When the platform rotates, grouping and ungrouping of body parts and a number of other exercises can be performed as instructed by the trainer.

Thus, the skater fulfills complex quick-coordination movements in conditions of movement with a large angular velocity ω _BP. . Such training, in conditions of forced rotation, reduces the time for mastering complex coordination movements and allows you to train the skater’s vestibular apparatus. For figure skating, the stability of the vestibular apparatus to fast rotations is the most important characteristic.

The simulator shown in Fig. 2 is as follows. The skater 7 without skates becomes on the platform 4. The suspension is fixed on the skater 7 - a safety belt 11 is put on the belt, on which straps 10 are connected, connected to the slings 9.

Then the assistant to the trainer turns on the engine 1 and, with the help of the speed control unit of the engine 6, starts accelerating the platform 4 together with the skater 7. Upon reaching the required angular speed ω _BP rotation of the platform 4, the skater 7 makes a jump into rotation. In this case, the crossbar 8 connected by slings 9 to the skater rotates in the bearing 12. In the jump, the trainer 18 pulls up the skater with the help of a cable 13 thrown over the block 14 and holds it for some time in the air in rotation. Thus, the skater fulfills the movement of the links of the body in flight at a high speed of rotation.

The simulator shown in Fig. 3 is as follows. The skater 7 without skates stands on the platform 4. The platform 4 located in the center of the podium 19 rotates the skater 7. When performing jumps from the rotating platform 4, the skater lands on the surface 21 of the podium 19. The diameter of the podium 19 must be at least 3 meters to ensure high-quality practicing the movements of the skater when landing after the jump and to avoid injuries when falling.

The simulator mounted on artificial ice and shown in Fig. 4 is as follows.

The skater 7 in ice skates rises on the platform and spins on it to the rotation speed set by the trainer. Upon reaching the desired speed of rotation, the skater 7 makes a jump into rotation and lands on the surface of the ice rink with artificial ice 23. Thus, the elements of movement are worked out when the skater lands after the jump.

The simulator shown in Fig. 5 is as follows. Depending on the athlete's level of fitness, the coach can change the height H of the location of the platform 4 relative to the base 2 when the skater jumps from the platform. Jumping from a height of H allows you to increase the duration of the skater's flight, which is important for practicing complex movements in flight.

The simulator shown in Fig. 6 is as follows. To imitate the conditions of the skater falling during landing and practicing methods to prevent falls, the skater jumps from an inclined rotating platform. The trainer can set the required angle of inclination of the platform α.

The simulator shown in Fig. 7 is as follows. The skater 7 in ice skates becomes on the platform 4. After spinning, the skater 7 jumps and lands on the surface of the ice rink with artificial ice 23. Landing on artificial ice, the skater can go on it after the spin to high speed. This provides a good training effect.

The simulator shown in Fig. 8 is as follows. The skater 7 in skates becomes on the platform 4. After spinning, the skater 7 makes a jump and lands on the synthetic ice cover 26 of the podium 19. Landing on the synthetic ice, the skater can go on it after the spin to high speed. This provides a good training effect.

The effect of using the proposed device is that the skater acquires the skill to perform complex coordination of fast movements in conditions of high angular velocities. After such a training, the process of mastering these movements in real conditions on ice is accelerated. At the same time, the device can be used both in the training room without skates and in ice skates on synthetic ice, and on a skating rink with artificial ice.

The proposed device can be implemented using modern electromechanical devices.

Claims (8)

1. A skater simulator comprising a platform mounted in a bearing, characterized in that a platform rotation motor, an overrunning clutch and an engine speed control unit are included in the composition, wherein the engine speed control unit is connected to the rotation engine. 2. The device according to claim 1, characterized in that it includes a skater body suspension system mounted on the cable of the block mechanism, while the axis of rotation of the platform is located along the line of tension of the cable. 3. The device according to claim 1, characterized in that it includes a podium, inside and in the center of which with a gap relative to the surface of the podium there is a platform so that the surface of the podium and the surface of the platform coincide in height relative to the base. 4. The device according to claim 1, characterized in that it is installed on the surface of the ice rink with artificial ice. 5. The device according to claim 1, characterized in that it is made with the possibility of changing the height of the platform relative to the base. 6. The device according to claim 1, characterized in that it is configured to tilt the platform relative to the base. 7. The device according to claim 1, characterized in that the platform mounted in the bearing, the freewheel and the platform rotation motor are integrated in the construction of the artificial ice rink. 8. The device according to claims 1 and 2, characterized in that the surface of the podium is provided with a coating of synthetic ice.