RU202891U1 - Wave Biomechanical Trainer - Google Patents

Abstract

The utility model relates to equipment for physical culture and health-improving gymnastics. The wave simulator contains a body 1, which contains a rod 2, a weight element 3, two springs 4 and two end elements 5. The ends of the springs 4 are attached to the rod 2 and the weight element 3. Technical result: increased reliability.

Description

The field of technology to which the utility model belongs

The utility model relates to equipment for sports and recreational activities, general physical training and sports warm-up, as well as to the field of medical physical culture for all segments of the population (children, adolescents, adults and the elderly, as well as the disabled).

State of the art

A wave biomechanical simulator is known from the prior art, containing a body in which a rod, a weight element, two springs, two end elements are located, said weight element is located on a rod with the possibility of longitudinal movement between the said springs (patent RU 111767, published on 27.12.2011). In this known simulator, the ends of the springs are not attached to either the weight member or the rod. For this reason, during the operation of the product, the elements may open, creating noise. Loose springs create the risk of the load jumping out of the body during sudden movements.

The essence of the utility model

The objective of this utility model is to improve performance.

As a result, the technical result is achieved, which consists in increasing the strength and reliability, as well as reducing the noise during the operation of the device.

The specified technical result is achieved by the fact that the wave biomechanical simulator contains a body in which a rod, a weight element, two springs, two end elements are located, the said weight element is located on the rod with the possibility of longitudinal movement between the said springs, one end of each of which is fixed on the weight element, and the other is fixed on a rod, the ends of which are connected to the body by means of end elements, while the simulator contains elements located on the rod that center the position of the rod in the body.

The specified technical result is also achieved by the fact that the load element is cylindrical and contains grooves at its ends, in which at least two coils of springs are located.

The specified technical result is also achieved by the fact that the ends of the springs are fixed to the rod by means of two nuts.

The specified technical result is also achieved by the fact that the end elements are connected to the ends of the rod by means of a nut and are made with the ability to damp the vibrations of the load element.

The specified technical result is also achieved by the fact that handles in the form of caps are installed at the ends of the housing.

The specified technical result is also achieved by the fact that a handle is installed on the body in the middle part.

List of drawing figures

FIG. 1 shows a sectional view of the device.

FIG. 2 shows the fastening of the springs to the load cell.

FIG. 3 shows the fastening of the springs to the rod.

Implementation of the utility model

In various sports and physical training methods, attempts are made to use the phenomenon of biomechanical resonance (BMR). The essence of the BMR phenomenon lies in the increase in the amplitude of the response of the active links of a person under external periodic influences, in the frequency range from 5 to 20 Hz. The effectiveness of this phenomenon is explained by the fact that the set tempo of rhythmic movements with the use of BMR is physiologically safe for the human body, and the nature and level of the load are permissible to the extent that they are allowed during normal physical exertion.

Sports equipment based on the BIS phenomenon can interact with the human body without an external source of vibrations, but only responding to natural vibrational and wave movements of a person in the frequency range (less than 5 Hz). The present utility model is a wave biomechanical sports equipment, i.e. hand-held portable simulator using the BIS phenomenon.

The wave trainer contains a body 1, in which a rod 2, a weight element 3, two springs 4, and two end elements 5 are located.

The body 1 is expediently made in the form of a circular tube with a diameter of 20 mm to 50 mm. It is possible to make housing 1 with a square section. The body material can be steel, aluminum alloy, durable plastic, composite material, or any other suitable material.

The load element 3 has an opening in which the rod 2 is located with the possibility of longitudinal movement between the springs 4 located in the housing 1 symmetrically. The section of the load element 3 should be the same in shape as the section of the body 1. The load element 3 is located inside the body 1 with a small gap allowing the load element 3 to make return movements along the rod 2. The load element 3 is preferably made of steel.

At both ends, the load element 3 is pressed by the springs 4. The springs 4 inside the body 1 can be installed both in a normally compressed state, and in a normally extended or neutral state. The way the springs 4 are normally loaded depends on the desired dynamic characteristics of the simulator.

The springs 4 can have both a cylindrical shape and a conical shape, and the apex of the cone can face both the load element 3 and the ends of the body 1. The springs 4 can have either the same pitch of turns or different. The parameters of springs 4 are selected based on the desired type of training.

One end of each of the springs 4 is attached to the weight element 3 (see Fig. 2), and the other is attached to the end of the rod 2 (see Fig. 3).

The ends of the rod 2 are connected to the body 1 by means of end elements 5.

The simulator contains elements 6 located on the rod 2, centering the position of the rod 2 in the housing 1. The centering elements 6 can be made in the form of plastic disks with a hole into which the rod 2 passes with a slight interference. Along the outer contour, the centering elements 6 are fitted with an interference fit inside the housing 1. Centering the rod 2 further increases the reliability of the device.

The load element 3 can be cylindrical and contain grooves 7 at its ends, in which at least two turns of the springs 4 are located. The grooves 7 have a groove on the end side, into which the initial turns of the spring 4 pass until they are completely closed. The ends of the springs 4 can be fixed to the weight element 3 in any suitable way, for example by welding.

The ends of the springs 4 can be fixed to the rod 2, for example, by means of two nuts 8 or by welding. The end parts of the rod 2 may have a thread onto which the first nut 8 is screwed, the diameter of which is greater than the diameter of the initial coil of the spring 4. When the initial coil of the spring 4 rests against the first nut 8, the second nut is screwed on with an interference fit securely fixing the spring 4 on the rod 2. You can use means that prevent the nuts 8 from loosening, for example, washers, etc.

The end elements 5 can also be connected to the ends of the rod 2, for example, by means of a nut 9 or by welding. End elements 5 can be made with the ability to damp vibrations of the load element. The damping effect is achieved by choosing a resilient material (eg spring steel or plastic) and a poppet shape of the element.

To further increase the reliability of the device, the ends of the housing 1 can be equipped with handles 10 in the form of caps, preferably made of plastic (PVC, polyethylene or other suitable material). Depending on the length of the exercise machine, a handle (not shown) can also be installed on the body 1 in its middle part. It is advisable to make the handles 10 of plastic and apply an anti-slip relief to the surface. The handles can have a wavy surface for a more comfortable grip by the user's hand.

The simulator can have a length of 30 cm to 2 m, depending on the desired type of load on the human body.

The device works as follows.

The practitioner tightly holds the body 1 by its ends or the middle part in one or two hands and imparts to the device reciprocating movements along the longitudinal axis with the frequency at which the load element 3 begins to vibrate along the rod 2.

The springs 4 are deformed and impart oscillatory wave movements to the load element 3, which are transmitted through the body 1 to the body of the student.

The intensity of the vibrational-wave movement of the load element 3 and the direction of the effect of the simulator on the body can be regulated by the trainee.

Depending on the goals of the training, the trainee independently excites the oscillations of the load element 3 of the desired amplitude and intensity, adaptive to the natural oscillations of his musculoskeletal system.

Fastening the ends of the springs 4 to the load element 3 and the rod 2 exclude the opening of the moving elements during the operation of the device, which reduces noise and increases the reliability of operation.

With the proper development of the methodology, the application of the present utility model can also have a medical effect, consisting in the normalization of the pulse, blood pressure and an increase in the general tone of the body.

Claims (6)

1. Wave biomechanical simulator, containing a body in which a rod, a weight element, two springs, two end elements are located, the said weight element is located on the rod with the possibility of longitudinal movement between the said springs, one end of each of which is fixed on the weight element, and the other - fixed on a rod, the ends of which are connected to the body by means of end elements, while the simulator contains elements located on the rod that center the position of the rod in the body. 2. The simulator according to claim 1, characterized in that the load element is cylindrical and contains grooves at its ends, in which at least two coils of springs are located. 3. The exercise machine according to claim 1, characterized in that the ends of the springs are fixed to the rod by means of two nuts. 4. The simulator according to claim 1, characterized in that the end elements are connected to the ends of the rod by means of a nut and are configured to damp the vibrations of the load element. 5. The simulator according to claim 1, characterized in that handles in the form of caps are installed at the ends of the body. 6. The exercise machine according to claim 1, characterized in that a handle is installed on the body in the middle part.

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