RU1817700C - Boxing training device - Google Patents

Description

FIELD OF THE INVENTION This invention relates to sports training equipment for generating boxing power.

The aim of the invention is to increase the usability of the simulator, for which the shock force sensor is made sound, i.e. when striking the simulator’s pneumatic shell with a force equal to or greater than the force that the simulator’s sensor is tuned to, the latter emits a sound signal informing the athlete about the force of his impact. The sound performance of the sensor, unlike the sensor with a visual scale, does not distract the athlete from the readings of the impact force sensor scale, allows practicing boxing combinations consisting of several strokes, does not limit the athlete's movement relative to the simulator around the circle, and stimulates the training effect.

The drawing shows the proposed boxing trainer.

The proposed boxing simulator comprises a pneumatic shell 3 suspended from a support. The suspension device includes a tube 1, the continuation of which is an elastic element 4, an arm 5, into the nozzle of which the other end of the elastic element is pressed in, a coupling of variable diameter 2, a wide portion of which is fixed to the shell using threads covering the sheath. The impact force sensor, the principle of which is based on the law of inertia of bodies, placed in the tube 1 includes a sound element 12 and a spherical-shaped drummer 7 mounted inside the sound element using a string 6. One end of the string is fixed to a diametrical partition 8 located in the tube, and the other is connected to the pin 9. The pin is fixed in the movable cup 13. The ends of the pin through the longitudinal grooves of the tube extend beyond the circumference of the tube and contact the spring surrounding the tube 10. The other end of the spring contacts the nut 11, tanovlenii on the threaded portion of the outer surface of the tube. Rotating the nut 11 carries out a different degree of tension on the string.

The sound element 12 is made in the form of a hollow cylinder, its outer diameter is smaller than the inner diameter of the tube and has sides at the ends on its outer surface. The beads are in close contact with the inner surface of the tube and keep the sound element from moving. The wall of the sound element has slotted slots arranged in such a way that the figure contoured by the slots has the shape of an O-shaped tuning fork. To prevent sound insulation, the portion of the tube surrounding the sound element has openings.

The axes of all the parts listed, with the exception of pin 9, match.

The pipe 1, within which the sonic force transducer is located, is a thin-walled metal one. The threaded section is made on a separate hollow

cylinder with the smallest possible wall thickness and is mounted on the tube with screws. The longitudinal grooves of the tube have a length that does not limit the oscillations of the pin 9, taking into account the string draw. There are three threaded holes along the circumference line of the installation of the diametrical partition, which is a disk with a diameter equal to the inner diameter of the tube, having a cylindrical hole in the center; the parts of the screws protruding from the screw holes inside the tube are the reference points of the diametrical partition. The portion of the tube surrounding the sound element also has openings,

reducing sound insulation. The elastic member 4 is a piece of steel wire with a diameter equal to the inner diameter of the tube. The fixed connection of the tube and the elastic element is carried out

using epoxy glue. The working length of the elastic element depends on its diameter and with a diameter of 24 mm, its length is 120 mm. The bracket 5 is made of a thin steel plate with attached to

it using electric welding pipe. The inner diameter of the bracket pipe is equal to the diameter of the elastic element. The elastic element is fixed in the pipe of the bracket by epoxy adhesive. Coupling

variable diameter 2 is made of a metal disk-shaped plate; repeating the shape of the surface part of the pneumatic shell, and a pipe with an inner diameter equal to the outer

tube diameter. The connection of these coupling elements is done by electric welding. The pneumatic casing is fastened to a wide section of the coupling by means of threads covering the casing, for which

In the larger circumference of the wide section, there are holes on which the ends of the threads are fixed. The connection of the sleeve of the coupling 2 with the tube 1 is made using screws, for which purpose on the sleeve of the coupling and the tube

there are three pairs of matching holes, the holes being threaded on the tube. The diameter of the movable cup 13 and the portion of the tube surrounding it are mated by a sliding fit. To avoid time-consuming

trocar operations at this tube site

an additional hollow cylinder is inserted, mating with its outer surface with the inner surface of the tube by a press fit, and the inner with the surface of the cup, sliding. A hole with a diameter equal to the diameter of the string was drilled in the center of the bottom of the glass; two diametrical holes were drilled in the cylindrical wall of the cup with a diameter mating with the diameter of the pin by a press fit. String b is a cable twisted from several thin steel wires. The spherical drummer 7 has a diametrical hole with a diameter equal to the diameter of the string. The fixation of the hammer on the string is carried out by soldering. The dimensions of the sound element are selected experimentally by a selection method, depending on the volume of the sound being emitted. The sound volume has a satisfactory sound element 100 mm long, with a wall thickness of 3 mm, made of bronze. The sides of the sound element have threaded holes for fixing it in the tube. When assembling the simulator, parts 1, 4, 5 are connected; installation of threaded, intermediate and sound cylinders. Separately connected parts 8, 6, 7, 13; tracing of these parts is introduced into the tube cavity, the holes of the longitudinal grooves of the tube and the cup are aligned and the pin 9 is pressed in. The parts 2,3 are separately mounted and, completing the assembly process, they are connected to the tube.

The principle of operation of the sonic force sensor of the simulator, as already noted, is based on the law of inertia of bodies and is as follows. When striking the pneumatic shell in the direction indicated by the arrow on the drawing, the tube 1 together with the sound cylinder 12 comes into motion in the same direction. Since the shock element 7 is inert, and is mounted on an elastic suspension, it lags behind in its movement, i.e. oscillates relative to the sound cylinder. At a certain impact force, the amplitude of the oscillation of the hammer is such that the hammer is in contact with the inner surface of the sound cylinder emitting the sound signal. The greater the tension force of the string, which is changed by the spring 10 and nut 11, the greater the corresponding impact force at which the sound force sensor is triggered.

When training on the proposed simulator, the athlete adjusts the shock force sensor to the maximum force of his blows by alternately striking the pneumatic shell and rotating the nut

11. The adjustment continues until after the minimum angle of rotation of the nut in the direction of increasing the impact force, the sensor stops responding. With this position of the nut, the athlete is trained; the sensor triggering in this position of the nut indicates an increased strength of the athlete's impacts. With stable sensor responses, the athlete turns the nut to the minimum angle at which the sensor stops functioning and continues the training process, etc. Comparison of the strength of these attacks with the original,

5 and a comparison of the impact forces of different athletes is made according to the number of thread patterns between the respective impact forces of the risks and the angle of rotation of the nut.

Claims (3)

1. A boxing simulator comprising a pneumatic shell suspended from a support and a shock force sensor in communication with it, characterized in that, for the purpose of 5 to improve ease of use, the pneumatic casing is suspended from the support through the elastic element pressed into the bracket pipe, covering its tube and a coupling of variable diameter, wide 0 the portion of which is fixed on the shell with the help of threads covering the shell, and the force sensor is made sound, placed in the tube and includes a sound element and a spherical drum mounted on a diametric string, one end of which is fixed on the diametrical partition placed in the tube, and the other associated with a spring-loaded pin mounted in the longitudinal grooves of the tube and 0 fixed in a movable cup, while the tube is made with a threaded portion on the outer surface on which a nut is mounted in contact with the spring. 5 2. Trainer pop. 1, characterized in that the sound element is made in the form of a hollow cylinder, the outer diameter of which is less than the inner diameter of the tube, with sides at the ends 0 of its outer surface, which is in close contact with the inner surface of the tube, and the cylinder wall has slotted slots located in such a way that the figure is contoured by the slots 5 has the shape of a C-shaped tuning fork, and the portion of the tube surrounding the sound element has holes. 3. The simulator according to Claim. 1, with respect to the fact that the axis of the string, drummer of the sound element, glass, tube, nut, elastic element, pipe bracket, coupling and pneumatic shell match.