RU86883U1 - RESPIRATORY TRAINING DEVICE - Google Patents

Abstract

A respiratory training device comprising a breathing tube to which a housing is attached, in which a low-frequency mechanical generator of air vibrations is placed, and a bypass chamber with an inhalation pipe in which an inspiratory valve is installed is formed, 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 body of revolution expanding upwards — a saddle in which a spherical ball is placed, and an outlet channel in common with the environment in which the exhalation valve is installed, characterized in that the exhalation valve is configured to control the resistance to the flow of exhaled air and is equipped with a valve pressing force regulator, which includes a spring and means for changing the degree of spring tension in the form of a sleeve fixed to the end of the output channel by means of a threaded connection with the possibility of axial movement.

Description

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.

The prior art device for breathing training, containing a breathing tube to which is attached a housing in which a low-frequency mechanical generator of air vibrations is fixed and a bypass chamber with an inhalation port is installed in which the inspiration valve is installed, 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 body of revolution expanding upwards — a saddle in which a spherical tube is placed Rick, and the outlet communicating with the environment in which is mounted an exhalation valve (RU 2306161 C1, A63B 23/18, 2007). The main disadvantage of this device is the difficulty of regulating the resistance to the flow of exhaled air, which is determined by the position of the spherical ball in the input channel of the vibration chamber, which is fixed in the housing with the possibility of rotation relative to the horizontal axis, which complicates the training process and reduces its effectiveness.

The utility model is aimed at increasing the efficiency of using the device for breathing training by providing the ability to control the resistance to the flow of exhaled air.

The solution to this problem is provided by the fact that in a device for breathing training containing a breathing tube to which a housing is attached, in which a low-frequency mechanical generator of air vibrations is placed and a bypass chamber with an inhalation pipe in which an inspiration valve is installed, while a low-frequency mechanical air generator is installed oscillations includes a vibration chamber with an inlet channel connected to the breathing tube, which is made in the form of a body expanding upward of rotation - a saddle, in which According to a utility model, the exhalation valve is configured to control the resistance to the flow of exhaled air and is equipped with a valve pressing force regulator, which includes a spring and means for changing the degree of spring tension in the form of a sleeve mounted on the end of the output channel by means of a threaded connection with the possibility of axial movement.

The presence of an exhalation valve pressure force regulator in the output channel of the vibration chamber allows simple and accurate adjustment of the resistance to the flow of exhaled air and, accordingly, fine-tuning of the respiratory training device in resonance mode, which increases the efficiency of the training process.

Figure 1 presents a General view of a device for breathing training; figure 2 is a section aa in figure 1.

The device for breathing training contains a breathing tube 1 with a mouthpiece 2, to which a housing 3 is attached, in which a low-frequency mechanical generator of air vibrations 4 is placed and a bypass chamber 5 with a nozzle 6 of a breath in which a valve 7 of a breath is installed is formed. The inspiration pipe 6 may be provided with a tubular nozzle 8. The low-frequency mechanical generator of air vibrations 4 includes a vibration chamber 9 with an inlet channel 10 connected to the breathing tube 1, which is made in the form of a seat expanding upward of the body of revolution — a saddle in which the spherical ball 11 is placed, and the output channel 12 in communication with the environment in which the exhalation valve 13 is installed, which is configured to control the resistance to the flow of exhaled air and is equipped with a valve 14 pressure control valve tory includes a spring 15 and means for changing the spring tension of degree 15 as a sleeve 16 attached to the output end of the channel 12.

A device for breathing training operates as follows.

When inhalation is performed due to vacuum, the inspiratory valve 7 opens and air from the tubular nozzle 8 passes through the inspiratory nozzle 6 into the bypass chamber 5 of the housing 3 and enters the oral cavity through the breathing tube 1. In this case, the exhalation valve 13 is closed, and the spherical ball 11 under the influence of gravity blocks the conical seat - the input channel 10 of the vibration chamber 9 of the low-frequency mechanical generator 4 of air vibrations. When exhalation is performed under the pressure of exhaled air, the inspiratory valve 7 closes, blocking the inspiratory nozzle 6, and the air flow from the bypass chamber 5 of the housing 3, raising the spherical ball 11, enters the vibration chamber 9 of the low-frequency mechanical generator 4 of air vibrations through the conical seat - inlet channel 10 and, opening the exhalation valve 13, through the outlet channel 12 enters the environment, overcoming the resistance of the vibration chamber 9 and the exhalation valve 13 in the outlet channel 12.

The spherical ball 11 as a result of interaction with the air flow in the upwardly expanding input channel 10 of the vibration chamber 9 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. Moreover, the position of the spherical ball 11 (lift 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 by establishing the phenomenon (mode) of resonance, determined by the maximum amplitude of the oscillations (height of rise) of the spherical ball 11, when the frequency of low-frequency vibrations of the spherical ball 11 approaches the frequency of natural vibrations of 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.

By rotating the sleeve 16 of the valve pressing force regulator 14, the degree of tension of the spring 15 of the exhalation valve 13 can be changed in the form, the resistance to the flow of exhaled air can be adjusted, and the position of the spherical ball 11 in the output channel 10 of the vibration chamber 9 can be adjusted and, accordingly, the device can be adjusted precisely and simply for breathing training in resonance mode, which increases the efficiency of the training process.

Claims (1)

A respiratory training device comprising a breathing tube to which a housing is attached, in which a low-frequency mechanical generator of air vibrations is placed, and a bypass chamber with an inhalation pipe in which an inspiratory valve is installed is formed, 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 body of revolution expanding upwards — a saddle in which a spherical ball is placed, and an outlet channel in common with the environment in which the exhalation valve is installed, characterized in that the exhalation valve is configured to control the resistance to the flow of exhaled air and is equipped with a valve pressing force regulator, which includes a spring and means for changing the degree of spring tension in the form of a sleeve fixed to the end of the output channel by means of a threaded connection with the possibility of axial movement.