RU185089U1 - Breathing device - Google Patents

Abstract

The utility model relates to means for training breathing by creating additional resistance to the flow of exhaled air and is aimed at increasing the efficiency of the training process. A device for training breathing, comprising a housing of a low-frequency mechanical generator of air vibrations with a bypass chamber, to which a breathing tube with a mouthpiece and an inhalation pipe are connected, inspiratory valve, while the low-frequency mechanical generator of air vibrations includes a vibration chamber with an inlet channel connected to the breathing tube, which is made in the form of a cone-shaped saddle expanding upward, in which the spherical body is placed - a ball, and an outlet channel in communication with the environment in which the exhalation valve is installed, while the spherical body - ball is made of stainless steel steel grade 12X18H10T, while its mass is 8.6 ÷ 8.8 g, and the diameter is 11.9.0 ÷ 12.1 mm.

Description

The utility model relates to means for breathing training by creating additional resistance to the flow of exhaled air and is aimed at increasing the efficiency of the training process.

A breathing training apparatus is known in the prior art, in a breathing training apparatus comprising a housing of a low-frequency mechanical air oscillation generator with a bypass chamber, to which a breathing tube with a mouthpiece and an inhalation pipe provided with an inspiratory valve are attached, while the low-frequency mechanical air oscillation generator includes a vibration a chamber with an inlet channel connected to the breathing tube, which is made in the form of a cone-shaped saddle expanding upwards, in which but the spherical body - the ball, and the outlet communicating with the environment where the exhalation valve is arranged (RU 2306161 C1, A63V 23/18, 2007; RU 86883 U1, A63V 23/18, 2009). The main disadvantage of this device is the difficulty of accurately regulating the flow of exhaled air to establish a resonance mode when the frequency of low-frequency oscillations of the ball in the low-frequency mechanical generator of air vibrations approaches the frequency of natural vibrations of the walls of the trachea of the user in the process of breathing training, which reduces the effectiveness of the claimed device on the urgent adaptation process physical activity and, accordingly, the effectiveness of the training process.

The technical result, which the utility model is aimed at, is to increase the effect of training the respiratory muscles by choosing the optimal ratio of mass and diameter of the ball, and, accordingly, to increase the efficiency of the training process.

In addition, the utility model is aimed at increasing the efficiency of using the device for breathing training by providing the ability to accurately customize the low-frequency mechanical generator of air vibrations in resonance mode by regulating the flow of exhaled air.

The solution to this problem is provided by the fact that in a device for breathing training, comprising a housing of a low-frequency mechanical generator of air vibrations with a bypass chamber, to which a breathing tube with a mouthpiece and an inhalation pipe equipped with an inspiratory valve are attached, the low-frequency mechanical generator of air vibrations includes a vibration chamber with an inlet channel connected to the breathing tube, which is made in the form of a cone-shaped saddle expanding upwards, in which a spherical the body of the body is a ball, and the outlet channel in communication with the environment in which the exhalation valve is installed, according to a utility model, the spherical body is a ball made of food grade 12X18H10T stainless steel, and its mass is 8.6 ÷ 8.8 g, and the diameter is 11.9.0 ÷ 12.1 mm.

In addition, the output channel is equipped with an end regulating sleeve with a variable diameter - the bore of the axial hole.

Preferably, the axial hole of the end of the regulating sleeve is made in the form of an iris diaphragm containing a system of petals, each of which is mounted on a movable ring element, which is mounted in a fixed cylindrical frame.

In addition, the exhalation valve can be equipped with a valve pressing force regulator, which includes a spring and means for changing the compression ratio — the length of the spring in the form of a thrust ring attached to the end control sleeve, which is mounted on the housing of the output channel with the possibility of axial movement by means of a threaded connection.

The claimed ratio of mass (8.7 ± 0.1 g) and diameter (12.0 ± 0.1 mm) of a ball made of food grade stainless steel 12X18H10T ensures the creation of positive oscillatory pressure during exhalation with a certain load on the respiratory muscles and the oscillation frequency of the exhaled air, which increase the effect of training respiratory muscles and, accordingly, breathing exercises.

The presence in the output channel of the vibration chamber of the claimed device of the end regulating sleeve with a variable diameter -bore section of the axial hole, which is preferably made in the form of an iris diaphragm containing a system of petals, each of which is mounted on a movable annular element that is mounted in a fixed cylindrical frame, provides precise control of the flow of exhaled air and, accordingly, accurate individual adjustment of the low-frequency mechanical air generator oscillations in resonance mode, which also increases the efficiency of the training process. In addition, the presence of an exhalation valve pressure force regulator located in the output channel of the vibration chamber, which allows you to further adjust the resistance to the flow of exhaled air and, accordingly, also increases the efficiency of the training process.

In FIG. 1 is a perspective view of a breathing apparatus; in FIG. 2 is a section AA in FIG. one.

A device for breathing training comprises a housing 1 of a low-frequency mechanical generator of air vibrations with a bypass chamber 2, to which a breathing tube 3 with a mouthpiece 4 and an inhalation pipe 5, equipped with an inhalation valve 6, are connected. The low-frequency mechanical generator of air vibrations includes a vibration chamber 7 with an inlet channel 8 connected to the breathing tube 3, which is made in the form of a cone-shaped saddle expanding upwards, in which a spherical body - a ball 9 is placed, and with an outlet channel 10 in communication with the environment is equipped with a valve 11 exhale and the end of the regulating sleeve 12 with a variable diameter - the bore of the axial hole. Moreover, the spherical body - ball 9 is made of food grade stainless steel 12X18H10T, while its mass is 8.7 ± 0.1 g and its diameter is 12.0 ± 0.1 mm.

Preferably, the axial hole of the end of the regulating sleeve 12 is made in the form of an iris diaphragm containing a system of petals 13, each of which is mounted on a movable ring element 14, which is mounted in a stationary cylindrical frame 15.

In addition, the exhalation valve 11 may be equipped with a valve pressing force regulator, which includes a spring 16 and means for varying the compression ratio — the length of the spring in the form of a thrust ring 17 attached to the end regulating sleeve 12, which is mounted on the housing 18 of the output channel with axial movement threaded connection.

The inspiration pipe 5 may be provided with a tubular nozzle 19. For ease of use, the respiratory training device is provided with a fastening means 20 on the user's head.

A device for breathing training operates as follows.

In the process of breathing training, the user takes the mouthpiece 4 of the breathing tube 3 into the mouth. When inhalation is performed due to vacuum, the inhalation valve 6 opens and air from the tubular nozzle 19 passes through the inhalation pipe 5 into the bypass chamber 2 of the housing 1 and enters the oral cavity through the breathing tube 3. In this case, the exhalation valve 11 is closed, and the ball 9, under the action of gravity, blocks the cone-shaped saddle of the inlet channel 8 of the vibration chamber 7 of the low-frequency mechanical generator of air vibrations. When exhalation is performed under the pressure of exhaled air, the inspiratory valve 6 closes, blocking the inspiratory nozzle 5, and the air flow from the bypass chamber 2 of the housing 1, raising the ball 9, enters through the cone-shaped seat of the inlet channel 8 into the vibration chamber 7 of the low-frequency mechanical generator of air vibrations and, opening exhalation valve 11, passes the outlet channel 10 and through the axial hole of the iris diaphragm of the end regulating sleeve 12 enters the environment, overcoming the vibration resistance to amers 7 and exhalation valve 11.

The ball 9 as a result of interaction with the air flow in the upwardly expanding cone-shaped saddle of the input channel 8 of the vibration chamber 7 begins to perform low-frequency forced oscillations, and, like a mechanical vibrator, modulates the oscillations of the exhaled air and, accordingly, the walls of the respiratory tract, in particular the trachea. In this case, the position of the ball 9 (lifting height) at the time of exhalation is determined by the instantaneous value of the positive pressure (pressure) of the exhaled air and is controlled by the exhalation of the user.

The optimal effectiveness of the claimed device for breathing training is achieved when establishing the phenomenon (mode) of resonance, determined by the maximum amplitude of the oscillations (lift height) of the ball 9, when the frequency of low-frequency vibrations of the ball 9, which depends on its mass and shape - diameter, approaches the frequency of its own fluctuations in the walls of the trachea. In this case, there is a sharp increase in the amplitude of the modulated (forced) oscillations of the exhaled air and the walls of the respiratory tract - the trachea, which stimulates the smooth muscles of the lungs and leads, due to the manifestation of the bronchodilating effect, to urgent adaptation to physical activity when performing cyclic exercises in a shorter time. The optimal effectiveness of the claimed device for breathing training is achieved when establishing the phenomenon (mode) of resonance, determined by the maximum amplitude of the oscillations (lift height) of the ball 9, when the frequency of low-frequency vibrations of the ball 9, which depends on its mass and shape - diameter, approaches the frequency of its own fluctuations in the walls of the trachea.

By rotating the lead 20 of the movable ring element 14, it is possible, by changing the bore of the axial hole of the iris diaphragm of the end regulating sleeve 12, to control the flow rate of the exhaled air and the position of the spherical ball 9 in the upwardly expanding cone-shaped seat of the inlet channel 8 of the vibration chamber 7, providing accurate individual adjustment of the low-frequency mechanical generator of air vibrations in resonance mode, optimal for the effectiveness of breathing training.

In addition, by rotating the end adjusting sleeve 12, it is possible to change the compression ratio — the length of the spring 16 and the pressing force of the exhalation valve 11, and further control the amount of resistance to the flow of exhaled air, expanding the range of fine tuning of the device for breathing training into resonance mode, which also increases the efficiency of the training process .

Example.

To assess the influence of the weight and dimensions of the ball 9, placed in the input channel 8 of the vibration chamber 7 of the low-frequency mechanical generator of air vibrations, made in the form of a cone-shaped saddle expanding upwards, an experiment was conducted.

The experiment was attended by 7 athletes (km, ms) who performed loads on a Monark mechanical bicycle ergometer (Sweden) with different pedaling power - 120 W and 200 W using the claimed breathing apparatus using a ball 9 with various parameters: steel balls with a diameter of 9.0 ± 0.1 mm and a mass of 3.7 ± 0.1 g, a diameter of 11.0 ± 0.1 mm and a mass of 6.7 ± 0.1 g, a diameter of 12.0 ± 0.1 mm and weighing 8.7 ± 0.1 g, diameter 13.0 ± 0.1 mm and weight 11.1 ± 0.1 g, diameter 15.0 ± 0.1 mm and weight 16.1 ± 0.1 g and a glass ball with a diameter of 12.0 ± 0.1 mm and a weight of 2.6 ± 0.1 g.

The duration of each load was 2 minutes. At the same time, the cadence was maintained at 80 rpm for the entire duration of the work. To take the exhaled air, a specialized (gas) mask equipped with a three-way valve or a simulator equipped with a special transitional device for intake was fixed on the athlete. exhaled air. The analysis of the concentration of gases in exhaled air (after they were taken into Douglas bags) was carried out on the units of the Beckman (USA) OM-II gasometric analyzer. In this case, the oxygen utilization coefficient (KIO2) was determined in% - an indicator characterizing the amount of oxygen 02 absorbed by the body from 1 liter of ventilated air, which reflects the degree of oxygen assimilation efficiency and the functioning of the body's oxidative system and, accordingly, the energy generation efficiency necessary to ensure muscle activity of a person. An increase in KIO2 characterizes an increase in the functioning efficiency of the respiratory muscles and the oxidative energy supply system of the athlete's motor actions, and, accordingly, an increase in the effectiveness of breathing training and the effectiveness of the training process as a whole. Table 1 shows the arithmetic mean of the oxygen utilization coefficient (%) for a group of 7 athletes at different load capacities of performing a test exhalation exercise.

An analysis of the results shows that with an increase in the diameter and mass of the ball, the oxygen utilization coefficient increases, increasing to a maximum value of 4.89 ± 0.28% at a power of 120 W and 5.66 ± 0.30% at a power of 200 W (p <0.05 ) for a steel ball with a diameter of 12.0 ± 0.1 mm and a mass of 8.7 ± 0.1 g. A further increase in the diameter and mass of the ball leads to a decrease in the oxygen utilization coefficient.

Thus, the claimed ratio of the parameters of the ball, in which its diameter is 12.0 ± 0.1 mm (or 11.90 ÷ 12.1 mm) and the mass is 8.7 ± 0.1 g (or 8.6 ÷ 8 , 8 g), is optimal and essential for obtaining a technical result, which consists in increasing the efficiency of training the respiratory muscles, and, accordingly, in increasing the effectiveness of breathing training and the effectiveness of the training process as a whole.

Claims (4)

1. A device for breathing training, comprising a housing of a low-frequency mechanical generator of air vibrations with a bypass chamber, to which a breathing tube with a mouthpiece and an inhalation pipe equipped with an inspiratory valve are attached, while the low-frequency mechanical generator of air vibrations includes a vibration chamber with an inlet channel connected to the respiratory a tube, which is made in the form of a cone-shaped saddle expanding upwards, in which a spherical body is placed - a ball, and an output channel communicated with a rusting medium in which an exhalation valve is installed, characterized in that the spherical body - ball is made of food grade 12X18H10T stainless steel, while its mass is 8.6 ÷ 8.8 g and its diameter is 11.9.0 ÷ 12.1 mm . 2. A device for breathing training according to claim 1, characterized in that the output channel is equipped with an end regulating sleeve with a variable diameter - the bore of the axial hole. 3. A device for breathing training according to claim 1 or 2, characterized in that the axial hole of the end regulating sleeve is made in the form of an iris diaphragm containing a system of petals, each of which is mounted on a movable ring element that is mounted in a fixed cylindrical frame. 4. A device for breathing training according to claim 1 or 2, characterized in that the exhalation valve is equipped with a valve pressing force regulator that includes a spring and means for varying the compression ratio — the length of the spring in the form of a thrust sleeve fixed to the output channel with axial movement by threaded connection.

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