RU75295U1 - DEVICE FOR STUDYING AND TRAINING HUMAN BODY STABILITY - Google Patents

Abstract

The utility model relates to medical equipment, namely, devices for studying and diagnosing equilibrium, as well as to the field of sports for assessing the psychophysiological state of a person during biomechanical studies of the musculoskeletal system and resistance training. The device for research and equilibrium training, proposed as a utility model, solves the problems of increasing the reliability of information and the objectivity of diagnostics, taking into account the physiological processes of maintaining equilibrium, as well as improving the stability training process by quickly creating comfortable, natural working conditions of the biological system. These tasks are achieved by the fact that in the known device for the study and training of equilibrium, containing a movable platform, including the upper and lower plates, as well as tilt measuring devices on the uprights, the upper and lower plates of the moving platform are elastically connected through the central stiffness unit, and tilt measuring devices the upper plate is connected to the electronic logic unit for measuring the time of conditional equilibrium and the number of posture corrections introduced into the device.

Description

The utility model relates to medical equipment, namely, devices for studying and diagnosing equilibrium, as well as to the field of sports for assessing the psychophysiological state of a person during biomechanical studies of the musculoskeletal system and resistance training.

In known devices for research and equilibrium training, stationary structures of stabilographs are traditionally used [2, 3], less often mobile platforms are used, the main disadvantage of which is the violation of the natural process of maintaining equilibrium and the need for “balancing” in the process of measurement or training [1] due to the lack of habitual stabilizing moment.

In the known device [4] for training the muscles of athletes, containing a movable platform for placing an athlete, installed on the base by means of a spring-loaded ball joint located in the housing, training is carried out by changing the angle of the platform according to a given program.

In the above device, the study and training of the equilibrium is in the mode of forced oscillations, which does not allow to obtain reliable data on the natural state of the equilibrium retention mechanism and the ways of its training.

In the known device [5] for detecting vibrations of the human body, a mobile platform is used with a limiter for displacements of the carrier plate and a shock absorber in the form of a system of compression springs.

The design under consideration acts as a kind of mechanical oscillation amplifier due to positive feedback and has a significant destabilizing moment instead of the natural stabilizing one, which also does not allow obtaining objective data on the process of maintaining equilibrium, methods for improving it and training.

In the known device [6, 7], the ability to maintain equilibrium in conditions as close to natural as possible is estimated. The design of the device [6, 7] contains two identical plates, the upper one is mounted in the center on the ball and propped up in the corners by spiral springs so that it can perform the rotational movements necessary for an adequate way to study the vibrations of the human body.

The disadvantage of this device [6, 7] is the violation of the equilibrium retention mechanism due to the absence of the usual stabilizing moment, which requires unnatural "balancing" in exaggerated conditions.

The closest in technical essence and selected as a prototype is the "Device for the study and training of equilibrium" [8]. The design of the device contains a movable platform, including at least two non-deformable plates, the upper of which is movable and rests on a central ball bearing. tensioned elastic blocks of stiffness, which has a stabilizing moment that is natural for the biological system.

In addition, its plates are resiliently connected so that the resulting rotational rigidity of the platform, adequate to the integral articular rigidity of the test's musculoskeletal system, is related to the angle of inclination of the upper plate relative to the lower in accordance with an exponential law.

To this end, the stiffening blocks contain two mounting frames having holes for platform mounting hooks, at least five coil springs of various lengths having corresponding hooks at their ends are fitted on the frames, springs of the same length are grouped in pairs and arranged symmetrically with respect to the central axis of the frame, their ends are fixed on the upper and lower frames.

And also due to the fact that the measuring devices for tilting the upper plate are multilevel and equipped with discrete sensors.

The disadvantages of this device [8] are the low manufacturability of the platform design, due to the need for accurate selection of four sets of springs of a strictly defined length, as well as low efficiency when replacing all stiffness blocks in the case of adapting the device to solve specific problems.

A device for studying and training the stability of the human body, proposed as a useful model, solves the problems of increasing the reliability of information and the objectivity of diagnosis, as well as improving the process of training stability by expanding the functionality of the device.

These tasks are achieved due to the fact that in the known device for the study and training of equilibrium [8], containing a movable platform formed by the upper and lower plates, as well as at least three measuring devices for tilting on racks, the upper and lower plates of the movable platform are elastically connected between themselves through a central stiffener made in the form of a set of cruciform plates of a cup-shaped shape with different curvatures of the base made of spring steel.

In addition, the central stiffener in the proposed model consists of a set of plates, each of which in turn has a radius of curvature of the base, ensuring the presence of gaps between the free ends of the plates in accordance with the dependence:

Δ _i = A ₀ [(i + 1) ln (i + 1) -ilni-1],

where Δ _i - the value of the "i" -th gap between the free ends of the plates, counting from the top;

i - natural numbers, starting from 1, which are serial numbers of gaps, starting from the top;

And ₀ is a constant coefficient for a particular design.

Also in the proposed utility model, the measuring devices for tilting the upper plate are multilevel and are equipped with discrete sensors, while these sensors are connected to an electronic-logic unit for measuring the conditional "equilibrium" time and the number of posture corrections introduced into the device.

To this end, the central stiffening block is made in the form of at least three cup-shaped elastic plates with different curvatures of the spring steel base and fastening both plates, which makes it possible to obtain a high-tech, simple, reliable platform design. Cup-shaped elastic plates can be of various configurations, in particular, split of at least four petals.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information, and the identification of sources containing information about analogues of the claimed utility model, allowed to establish that the applicant did not find any analogues characterized by features identical to all the essential features of the claimed utility model. The definition from the list of identified analogues of the prototype, as the closest in the set of essential features of the analogue, allowed us to identify the set of essential distinguishing features in relation to the applicant’s technical result in the claimed device, set forth in the utility model formula. Therefore, the claimed utility model has novelty.

The proposed design of the device according to claim 1, 2 is shown in figure 1, where

1 - bottom plate

2 - top plate,

3 - central support,

4 _ij - elastic plates of the central block of rigidity,

5 _1-4 - fixing screws,

6 - a fixing washer,

7 _1-4 - measuring devices for tilting the upper plate (shown conditionally).

The platform consists of undeformable lower (1) and upper (2) plates having at least three angles. A central support (3) is installed in the geometric center of the plates, consisting of a steel rod with a rounded end resting against a spherical recess of the upper plate. The lower threaded end of the central support is screwed into the threaded hole of the lower plate (1). The central support (3) compresses the fixing washer (6), which holds the central stiffness block, made in the form of a set of cup-shaped cross-shaped plates (4 _ij ). The upper plate of the central stiffening block is connected to the upper plate (2) of the platform by fixing screws (5 _1-4 ). The height of the central support (3) is controlled by the selection of the thickness of the retaining washer (6) so that when installed in the structure, there is an initial tension that secures the upper plate (2) to the central support (3) when the platform is tilted due to transportation or experimental conditions.

In the free space between the plates (1) and (2) of the platform there are at least three tilt measuring devices (7 _1-4 ), which are equipped with discrete sensors with any possible principle of operation (optical, magnetic, mechanical) mounted on racks.

Figure 2 presents a top view of the plates (4 _ij ) of the Central unit of rigidity of the device.

The central block rigidity is made of a set of cup-shaped cross-shaped plates (4, _1-3), and creates a non-linear rotational stiffness of the measuring platform. The material for the manufacture of the latter is spring steel, which provides a stable and linear characteristic of the stiffness properties of individual plates. All plates are completely symmetrical and identical to each other in all respects, except for the radius of rounding of the base. As a result, the free ends of the plates (4 _ij ) are separated by a certain distance. The value of this gap Δ _i between the free ends of the plates should provide a change in the resulting stiffness of the central block when the upper plate is tilted (2) in accordance with the exponential law [8]. In the case of using all plates (4 _ij ) with the same modulus of elasticity, the size of the gap, starting from the first from above the gap, is determined in accordance with the dependence:

Δ _i -A ₀ [(i + 1) ln (i + 1) -ilni-1],

where Δ _i - the value "i" -th gap counting from the top;

i - natural numbers, starting from 1, which are serial numbers of gaps, starting from the top;

And ₀ - constant for a particular design coefficient.

The stiffness of the plates (4 _ij ) of the central block is selected adequately for the weight of the subject and the objectives of the experiment, which provides an average value of the angular rotational stiffness of the entire platform within 1 ÷ 5 Nm / deg.

An individual selection of the rigidity parameters of the measuring platform is ensured by replacing the central unit with a similar, but with different rigidity, plates (4 _ij ), which the proposed device of the utility model is equipped with.

The proposed utility model - a device for studying and training the stability of the human body - works as follows. Before starting operation, the tilt measuring devices (7 _1-4 ) are connected to the electronic logic unit and the information display device (not shown in FIG. 1). The test subject stands on the platform so that the geometric center of the plates (1, 2) is between the feet, and the anteroposterior and lateral axes of the installation coincide with the frontal and sagittal axes of the human body, respectively. The upper plate (2) swings on the central support (3) due to the natural vibrations of the body in the process of holding a vertical posture. In this case, the usual stabilizing moment arises, caused by the nonlinear resulting rotational rigidity of the platform, determined by the central block of rigidity due to the sequential pressing of additional plates (4 _ij ) while increasing the relative angle of inclination of the plates (1, 2) of the platform, while maintaining equilibrium.

Tilt measuring devices (7 _1-4 ) are equipped with discrete sensors, their operation is determined by the tilt angle of the upper plate (2). The height of the sensors in the tilt measuring devices on all racks is such that the triggering of the sensors occurs when the tilt angle is the same in any direction.

In addition, tilt measuring devices (7 _1-4 ) are multi-level: several (in terms of the number of levels) discrete sensors are installed on a rack at different heights. The operation of all equal-height sensors occurs at the same angle of inclination identical for all racks.

Information from the tilt measuring devices (7 _1-4 ) through the electronic-logic unit is fed to the display of the information display device, where it clearly demonstrates the process of maintaining equilibrium.

In the case of the correct orientation of the body axes of the test subject and the platform, tilting the body lights up the indicator lamps of the corresponding direction. The intensity of the glow of the lamps increases with increasing angle of inclination of the upper plate, which signals a decrease in stability in this direction.

The electronic logic unit also measures the conditional “equilibrium” time in a given interval of the tilt angles of the upper plate (2), when the corresponding indicator

the lamps do not light, and also counts the number of conditional posture corrections when the indicator lamps light up and go out, for the experiment time assigned by the timer.

The device in question allows you to evaluate, diagnose and train stability both in vivo due to muscle sensations and with the introduction of visual feedback on the indicator board, which extends the functionality of the device.

The proposed device design, with prestressing, is autonomously independent and can be installed in any position relative to the horizon, which allows measurements and equilibrium training, including on an inclined surface. This feature of the device is necessary to assess the quality of sports exercises and study the repulsion mechanisms, as well as when designing ergonomic shoes for healthy people, or when prosthetics. Stability training on an inclined surface is necessary regardless of the type of human activity, which reduces injuries and increases the reliability and effectiveness of motor actions.

The proposed model allows you to quickly adapt the platform parameters to subjects with different body weights, as well as taking into account the research objectives by quickly replacing the central unit with the required stiffness parameters, which the device is equipped with. This operation does not require additional adjustment and adjustment of the device, which is especially important when using this device in conditions of child care facilities and mass physical education.

The design of the platform is very simple and reliable with a minimum number of parts, which determines the manufacturability of its manufacture and low cost.

Sources of information taken into account during the examination

1. Gurfinkel, B.C. Regulation of human posture / B.C. Gurfinkel, Ya.M. Kots, M.L.Shik // - M .: Nauka, 1965. - P.256.

2. Pat 2270603 RF, MKI A61B 5/103, A61G 11/00. Platform for the study of support reactions / A.G. Bilenko, G.P. Ivanova. - No. 2004121230; Announced July 12, 2004; Publ. 02/27/2006. - 7 p.: 4 ill.

3. Pat. 561556 USSR, MKI A61V 5/10. A device for recording the parameters of motion of the center of gravity of the human body / B.C. Gurfinkel, E.V. Gurfinkel, M.I. Lipshits. K.E. Popov. - No. 2134465/13; Stated 05.16.1975; Publ. 06/15/1977.- 4 pp.: 3 ill.

4. Pat. 1222288 A USSR, MKI A63V 23/04. A device for training the muscles of athletes / S.I. Gaba, B.C. Bartosh. - No. 3805076 / 28-12; Stated October 25, 1984; Publ. 04/07/1986. - 2 p.: 2 ill.

5. Pat.843949 USSR, MKI A61V 5/10. A device for recording fluctuations in the human body / V.G. Strelets, A.S. Korneev. - No. 2777956 / 28-13; Declared 07/04/1979; Publ. 07/07/1981. - 6 p.: 4 ill.

6. Pat. 42668 USSR, MKI A61V 5/10. Device for determining human stability / L.S.Soskin. - No. 155,546; Stated 1610.1934; Publ. 04/30/1935. - 2 p. 3 ill.

7. Ivanova, G.P. The equilibrium simulator-analyzer "TARIUS" / G.P. Ivanova, A.G. Bilenko // Theory and practice of physical. culture. - 1989. - No. 8. - S. 45-46.

8. Pat. 59955 RF for a utility model, MKI A61B 5/16, A61B 5/103, A61G 11/00. A device for the study and training of equilibrium / A.G. Bilenko, G.P. Ivanova. - No. 2006132796; Announced September 12, 2006; Publ. 01/10/2007. - 9 p.: 4 ill.

Claims (3)

1. A device for the study and training of equilibrium, containing a movable platform formed by the upper and lower plates, as well as at least three measuring devices for tilting on racks, characterized in that the upper and lower plates of the movable platform are elastically connected to each other through a central stiffener made in the form of a set of cruciform plates of a cup-shaped form with different curvatures of the base, made of spring steel. 2. The device according to claim 1, characterized in that the central block of rigidity consists of a set of plates, each of which in turn has a radius of curvature of the base, ensuring the presence of gaps between the free ends of the plates in accordance with the dependence: Δ _i = A ₀ [(i + 1) ln (i + 1) -ilni-1], where Δ _i is the value of the i-th gap between the free ends of the plates, counting from the top; i - natural numbers, starting from 1, which are serial numbers of gaps, starting from the top; And ₀ is a constant coefficient for a particular design. 3. The device according to claim 1, characterized in that the measuring devices for tilting the upper plate are multilevel and are equipped with discrete sensors, while these sensors are connected to the electronic-logic unit for measuring the conditional "equilibrium" time and the number of posture corrections introduced into the device.