RU2227056C1 - Method for developing experience of positional stability for sportsmen - Google Patents

Abstract

FIELD: physical development of human body. SUBSTANCE: method for developing experience of positional stability of sportsman comprises steps of forming on supporting surface small supporting force triangle with apex in mass center of sportsman and with base passing through heels of its leg foots when one straight leg is extended backwards at resting its whole foot upon supporting surface and turning knee of half-bent other leg aside from first leg while the whole foot rests upon supporting surface and is arranged normally relative to plane passing through heel of first leg, head occiput and mass center of sportsman; forming large force triangle with apex on head occiput and with base coinciding with base of small force triangle when body of sportsman with straight back is arranged vertically at facing front or it is turned to one side by angle less than 90 degrees relative to direction of outer load while placing occiput on line being extension of straight back of sportsman; at each application of load oriented in such a way that to distort positional stability of sportsman, changing position of sportsman due to simultaneously rotating and(or) moving its body and legs or its body relative to its legs until matching planes of above mentioned force triangles with vector of applied load. EFFECT: improved positional stability at outer loads. 2 cl, 6 dwg

Description

The present invention relates to the field of meeting the vital needs of a person, namely to the field of physical development of a person. In particular, the present invention relates to a method for training an athlete’s coordination of movement to form and develop skills of his positional stability. This method can best be applied to such forms of physical development that turn off the power of static and dynamic interactions of a discrete type, not subject to a time factor. Such forms of physical development include game sports, such as wrestling and any other martial arts, or sports games that include power contacts: for example, American football, rugby.

The most well-known ways of developing skills in developing technical techniques and positional stability of an athlete are methods based on the use of special technical means, sports equipment and simulators.

For example, there is a method of training athletes to develop coordination 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, but does not allow you to create sufficient physical stress on the human body when moving the body in space.

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

A known method of training coordination of movement, which consists in moving the body in space with a periodic change in its position with a force loaded, which allows you to develop skills of positional stability of the athlete by forming the reaction of the athlete to change in direction and magnitude of the external load aimed at removing him from the position of stable equilibrium (see EP 0488436, publ. 07.11.91). This method allows you to practice some movements that combine coordination and development of skills to maintain the positional stability of the 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 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 correct execution of techniques in minimal time periods, 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 statokinetic 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 method of training coordination of movement to develop the athlete’s positional stability to external influence, which consists in the formation of an athlete’s reaction to an external load that is variable in direction and magnitude, aimed at removing it from a stable equilibrium position (RU Patent No. 1776420, A 63 B 22/00, publ. 11/23/1992).

The known method of training 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 technical methods 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. Through repeated repetitions of techniques, along with the development of statokinetic noise immunity, athletes develop complex coordination motor skills.

The disadvantage of this method 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 relative to the geometric center of the platform, is subject to the inertial effects of various quantities. Due to the adaptability, after some time, the athlete begins to navigate on the platform and knows in advance at which distance from the center his pre-expected external force will be exerted. 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 basis of the invention is the creation of a method of training coordination of movement, in which various movements of the human body in space are carried out while creating favorable loads on the musculoskeletal system and the formation of a certain supporting positional posture, which allows the athlete to maintain positional stability regardless of the direction and magnitude of external force .

The technical result is an increase in the athlete’s resistance to external influences, which can be obtained by implementing the proposed method due to an effective, rather simple exercise training method 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.

According to the invention, the proposed method is aimed at developing skills in the development of mechanically occupied positionally stable racks, which allow counteracting both static and dynamic load without loss of stability of the athlete, and the development of coordination movements, which, if the stability is impaired, transform the previously occupied rack by the athlete into another, while maintaining stability both during the transformation and after it.

The specified technical result is achieved by the fact that in the method of developing skills of positional stability of an athlete, which consists in the formation of an athlete’s reaction to an external load that is variable in direction and magnitude, aimed at removing it from a stable equilibrium position, a small support force triangle with a vertex in the center is formed on the supporting surface the severity of the athlete and the base passing through the heels of the feet, moreover, one of the legs with the entire foot resting on the supporting surface in a straight position is put forward e, and the other with the entire foot resting on the supporting surface in a bent state, turn the knee away from the first leg with the foot perpendicular to the plane passing through the heel of the first leg, the back of the head and the center of gravity of the athlete, with the athlete’s body vertical with the back straight in position full-face or with a turn to one side at an angle of up to 90 ° with respect to the direction of the external load, form a large supporting force triangle with an apex on the nape of the athlete and a base coinciding with the base a small power triangle, while the back of the head is installed on the continuation of the straight back line, and with each application of external load, the position of the athlete is changed by simultaneously turning and / or moving his body and legs or body relative to his legs until the planes of these supporting triangles are aligned with the vector of the applied load.

In this case, the position of the athlete’s body is formed by tilting forward with the location of the straight back horizontally of the supporting surface or tilting back or half-tilting forward of the straight back.

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

When implementing this method, the athlete develops skills not only in the use of a positionally stable rack, but also in developing methods for coordinating the position of the legs, head, body and hands in space for the selected rack, for which a spatial geometric structure is organized that is maximally resistant to external force.

The present invention is illustrated by the specific examples presented in the drawings, in which Fig. 1 shows a positionally stable strut, the center position of the full-face, with a vertical arrangement of the body and put back with the right foot; figure 2 is the same as in figure 1, a left view at an angle of 45 °; figure 3 is the same as in figure 1, a left side view; figure 4 is the same as in figure 1, the position of the housing with a half inclination forward; figure 5 is the same as in figure 1, the position of the housing with an inclined back; figure 6 is the same as in figure 1, the position of the body with an inclined forward with a horizontally located back.

According to the present invention, the method of developing athlete’s positional stability skills is based on training in coordination of movement and developing the athlete’s statokinetic noise immunity to external force. This method consists in the formation by the athlete in the direction of the external force of a positionally stable rack by providing a spatially dependent position of the legs, head and body relative to each other and the supporting surface. With direct force impact on the athlete, aimed at removing him from a state of stable equilibrium, the latter changes the position of the body and legs to conduct resistance to force.

When forming a positionally stable stance, the athlete places the body with a straight back in full-face position or with a turn to one side at an angle of up to 90 ° while maintaining the location of the nape of the head on the line of continuation of the straight back and the projection of the athlete's center of gravity on the supporting surface on the line through the heels athlete's foot, the body is positioned vertically with a straight back or with an inclination forward with the location of a straight back horizontally of the supporting surface, or with an inclination back, or with an inclination forward of a straight back.

When both feet are placed on the supporting surface, the athlete puts one straight leg back, and the other leg in a bent state turns the knee away from the first leg with the foot perpendicular to the plane passing through the heel area of the first leg, the back of the head and the athlete's center of gravity.

The formation of this position is carried out in strict accordance with the spatial scheme, consisting of a small support force triangle with an apex at the athlete’s center of gravity and a base passing through the heels of the feet, as well as a large support force triangle with an apex on the nape of the athlete and the base coinciding with the base small power triangle.

Then, the athlete is exerted by external force by applying either a static load to it, for example, frontal or lateral, or by dynamic force, for example, by pushing or grabbing from the side of the partner (opponent), to bring the athlete out of a state of stable equilibrium. The athlete counteracts the static load by tensioning the muscles to fix the positionally stable spatial configuration of the rack, and the dynamic action is counteracted by the departure of body parts from the direction of the external disturbance or the reciprocal movements of the parts of the case, returning the forceful disturbance to the source of its creation, but subject to the combination of planes supporting triangles with applied load vector.

After conducting a technique for resistance to force, the athlete changes the position of the body and arms relative to the legs to form the initial positionally stable stance or positionally stable stance different from the original.

The implementation of this method allows not only the development of the athlete’s muscular system, but also forms the skills of assessing the degree of force impact, which allows the athlete to adequately respond to the force effect, which does not disturb his balance, and to the force effect, which takes him out of stable balance. In the first case, skills are formed for the adequate use of proprioceptive sensitivity, that is, the activity of the muscular system. In the latter case, skills are additionally formed to transform the position of the body parts to form a new stable posture, depending on the endurance of the vestibular analyzer.

The proposed method allows for the dynamic loading of all muscles of the athlete and coordinate not only the mutual spatial position of the body parts, but also associated with this spatial position of the movement, leading to the formation of a given spatial position of the body parts. The positional stability of an athlete, according to this method, is assessed as the ability to maintain stable balance by maintaining or changing a positionally stable stance regardless of the direction of the force disturbance and the time and speed of its action.

As a supporting surface, a non-moving stationary stationary surface, for example, a floor, a sports ground, a ring, can be considered. When performing a movable supporting surface, for example, rotatable, tilted or moved reciprocating, conditions of increased complexity are achieved to develop skills to maintain a stable state of the athlete when exerting a forceful disturbing effect on him.

The following are specific embodiments of the present invention.

When forming the central stable positional post shown in Figs. 1-3, the athlete places the body with a straight back vertically in the full-face position while maintaining the location of the nape of the head on the line of continuation of the straight back. In this case, the right straight leg is set back with the support on a full foot, and the left one is in a half-bent state, turns the knee to the side of the first leg with the foot perpendicular to the plane passing through the heel of the first leg, the back of the head and the athlete's center of gravity.

Such a dependent position of the body, legs and head is organized in strict accordance with the structural spatial system, providing increased rigidity to external loading. This structural system is based on the formation of stiffness triangles. Figure 1-3 shows the layout of these power triangles of rigidity. The large force supporting triangle A, B, C forms the athlete’s body stability with maximum rigidity in the plane of this triangle, that is, for force loading, the vector of which coincides with the plane of this triangle. The top C of this triangle is located in the nape of the head, and the corner points A and B of the base are in the zones of the athlete’s heels.

Stability is also organized by a small supporting force triangle A, B, D with a peak D in the zone of the athlete's center of gravity. The corner points A and B of the base of this triangle are also located in the zones of the athlete’s heels.

In this case, both triangles are located in the same plane, and the small supporting force triangle is located inside the main triangle, which in the direction of the full face of the athlete creates a stiff triangular structure that is resistant to the force acting in the plane of these triangles.

The power triangular structure with the location of the small support power triangle inside the large support triangle allows, depending on the direction of action of the external force action, to change the position of the sides of the main triangle while maintaining the spatial support triangular structure.

Thanks to this transformation, the athlete has the opportunity to strengthen the positional stability of the rack or deviate it from the direction of external force.

For example, as shown in FIG. 4, while maintaining a small stiffness support triangle, the straight-backed body can be positioned half-inclined forward. In this position, the relative location of the supporting triangles is maintained. The hypotenuse of the main triangle, which is the line of combining the thigh of the elongated back leg and back, performs the function of a stiffener.

As shown in figure 5, while maintaining the large and small supporting triangles, the housing can be tilted (folded) back. In this support column, the design of power triangles is two triangles located in the same plane.

When transforming the central support post in figure 1, the athlete has the opportunity to position the body horizontally with an inclination forward with the location of the straight back horizontally of the support surface (Fig, 6). As you can see, two power triangles with vertices D and C located in the horizontal direction at a distance from each other, allow to achieve maximum positional stability of the athlete in the direction of external force.

In any of the athlete’s central struts considered in full-face position, the projection of the athlete’s center of gravity on the supporting surface while maintaining the position of the legs is always projected onto the base line, which is the common base for both triangles.

The previously discussed examples of the formation of a positionally stable rack were based on the fact that when the body was located with a straight back while maintaining the location of the nape of the head on the line of continuation of the straight back, stability was achieved by a certain position of the body and legs, while the athlete put his right straight leg back with full foot , and the left leg in a half-bent state was unfolded by the knee to the side of the right leg, with the entire foot of this leg resting on the supporting surface.

The same effect in achieving positional stability is achieved when changing legs. That is, the left straight leg is set back, and the right, in a bent state, turns with the knee to the side of the left leg.

According to the present invention, the method can be characterized by the following actions:

1. On the athlete’s supporting surface, a small supporting force triangle is formed, the base of which passes through the heels of the feet, and the apex is located at the center of gravity of the athlete, whose feet are supported on the supporting surface, one straight leg is set back and the other is half bent the knee from the first leg with the location of the foot perpendicular to the plane passing through the heel area of the first leg and the back of the head of the athlete.

2. On the supporting surface of an athlete with a straight back in full-face position or turning to one side by an angle of up to 90 ° with respect to the direction of the external load, a large support force triangle is formed, the base of which coincides with the base of the small force triangle, and the vertex is located on the nape of the athlete, located on the continuation of the straight back line.

3. With each application of external load, the athlete's position is changed until the planes of the indicated supporting triangles are combined with the vector of the applied load.

Thus, it is possible to formulate the main technical problem, which is implemented by the proposed method. This task is to develop the athlete’s skills in positioning the body in such a position that the vector of the acting external load coincides with the aligned planes of the supporting triangles. In this case, the athlete's center of gravity will always be projected on the basis of these triangles, ensuring that his position on his legs is maintained. This method allows a purely technical approach to solving the problem of keeping an athlete in a standing position, which is especially important in conditions of dynamically changing discrete influences, which, for example, are an integral part of power and game sports, such as football, hockey, rugby, etc. d. When using the proposed method, injuries are significantly reduced, since a greater number of power actions that previously brought an athlete out of equilibrium can be perceived by an athlete without losing position on his legs.

The formation of the initial positionally stable rack, characterized not only by the creation of force triangles of rigidity, but also by fixing them with a muscle loaded, is the first stage of training for coordination of movement for the development of athlete's statokinetic noise immunity to external force exposure. In this case, training is possible both with the athlete's statically non-moving position on the supporting surface, and when the athlete moves along the supporting surface with the fixation of the statically positional stand when an external impact occurs.

In the future, the athlete is exerted by an external force effect, expressed in the form of a simulation of this effect (the direction of the action is shown, a shock, a push is simulated), and in direct contact with the load (for example, force contact with a partner).

When a force is applied to an athlete aimed at removing him from a state of stable equilibrium, the latter changes its position at each application of the indicated load by simultaneously turning and / or moving its body and legs or body relative to the legs until the planes of the indicated supporting triangles are aligned with the vector of the applied load.

During the technical reception, the athlete must maintain positional stability, that is, must be in a positionally stable stance. Maintaining a stance, that is, the position of the legs relative to the body or body relative to the legs with the projection of the center of gravity on a line passing through the athlete’s heels, is an essential aspect of training to coordinate movement to maintain a stable position.

In relation to the training, the implementation of the formation of supporting force triangles is carried out using technical means. For example, in order to fulfill the conditions of constant retention of the straight back and the nape of the athlete’s head on the back extension line, the body and head of the athlete are fixed relative to each other, for example, with a bandage. Fixation of the mutual position of the legs on the supporting surface can be carried out using the appropriate supports attached to the legs. These simple technical means are necessary for the formation of control by the athlete on the position of the legs when changing the position of the body. The reaction to this control is the tension of the muscles of the legs and body, forming a muscle corset that fixes the stance. Since the change in the position of the body relative to the legs is a transition process, it is accompanied by inertial loads that additionally affect the athlete and bring him out of a state of stable equilibrium. To neutralize the inertial effects, the athlete can carry out manipulations with his hands, the neutralization of the overturning moment will depend on the direction of action of which.

It is essential for the implementation of the method to monitor the position of the corner points of the supporting triangles during training, which is realized by attaching coordinate sensors (or displacement sensors) to these points, connected to a computer system for receiving signals from sensors, converting signals into a given protocol for processing them, and outputting them to a monitor for visual assessment of the position of power triangles during training in relation to their required position. Such systems are currently widely used to monitor the functioning of an athlete during training.

For interactive intervention in the training process, electric signaling devices can be fixed in the position of the coordinate sensors, which are point biostimulators designed to generate electrical pulses that occur when a computer records a displacement of one of the coordinate sensors from its required position.

In the framework of this application, a detailed device of such a system is not given, since such a system is currently widely used not only to monitor the athlete’s condition during training, but also to create films (I’ll take them through the corresponding sensors of the parameters of human movement and programmatically transfer them to the drawn character to give him human movements).

You can also use a system that includes radiation sources attached to the athlete, radiation data reception sources associated with the coordinate display system of the points of position of the limbs of the athlete and the calculation of motion parameters. For example, such a system is described in RU, 2106171, publ. 03/10/1998

Patterns can also be used, repeating the stance that the athlete must occupy, and representing, for example, rod elements fixed between themselves, or optical means can be used to control the position of individual points on the athlete's body.

This method allows you to develop coordination of the movements of the athlete and is a training for the formation of the statokinetic noise immunity of the wrestler. This method allows without the use of special training devices and devices to develop a stable reflex for a wrestler to maintain a stable position of the body to external influences. The method allows to develop the functions of the vestibular analyzer due to constant monitoring of the position of body parts relative to each other, not only in a static state, but also in the production of counteraction to external influences.

Claims (2)

1. A way to develop the skills of positional stability of an athlete, which consists in the formation of a response of an athlete to an external load that changes in direction and magnitude, which leads him out of a stable equilibrium position, characterized in that the athlete is occupied with a straight back position on the supporting surface when viewed from the front or with rotation to one side at an angle of up to 90 ° with respect to the direction of the external load with the formation of a support force triangle with a vertex in the nape of the neck, located on the extension of the line a straight back, one of the legs with the entire foot resting on the supporting surface in the upright position is set back, and the other, with the whole foot resting on the supporting surface in a half-bent state, unfolds away from the first leg with the foot located perpendicular to the plane passing through the heel of the first leg , the nape and the center of gravity of the athlete, with the formation of a supporting force triangle with the apex at the center of gravity of the athlete and the base passing through the heels of the feet of his legs, coinciding with the base of the first of a triangle, with each application of an external load, the position of the athlete changes by turning and / or moving his body and legs or body relative to his legs until the planes of the supporting triangles are aligned with the vector of the applied load. 2. The method according to claim 1, characterized in that the athlete’s body is positioned vertically, either with an inclination forward with a straight back horizontally of the supporting surface, or with an inclination back or half inclination forward of a straight back.

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