RU2118542C1 - Individual respiratory trainer - Google Patents

Abstract

FIELD: training of respiratory musculature. SUBSTANCE: trainer has external vessel with holes for communication with surrounding atmosphere and for respiratory tube coupled to internal chamber having holes in lower part and placed in middle vessel which has upper hole for communication with external vessel medium. Trainer also has facilities for separation of part of external vessel volume used and facilities for changing the value of flow section area of holes in lower part of internal chamber. EFFECT: continuous variation of training load. 6 cl, 4 dwg

Description

 The invention relates to the field of healthcare, in particular to devices (devices, instruments) that, due to inhalation-expiration resistance, hypercapnia and hypoxia of the inhalation medium, provide therapeutic (and / or preventive) hypercapnic effects together with hypoxic stimuli and training of respiratory muscles.

 A device (inhaler) is known, which is an external vessel in which a tube is coaxially located, on the side surface of the lower end of which holes are made for the passage of air sparged through the liquid [1].

 The known device is used as an inhaler and is unsuitable for providing therapeutic and prophylactic effects of hypercapnic along with hypoxic stimuli and training of respiratory muscles.

 A device (inhaler) is known that is closest in technical essence, containing an external vessel with an opening for communication with the surrounding atmosphere and with an opening for a breathing tube connected to an internal chamber having openings in the lower part and placed in a middle vessel made with an opening at the top for communication with the environment of the external vessel [2].

 The known device - the inhaler is intended primarily for use as an inhaler and does not provide means that would allow it to be used as an individual respiratory simulator, that is, a device with an individual and continuously variable complex (i.e., by inhalation-expiration resistance together with the degree of hypercapnia and hypoxia of the inhalation medium) by the training load in accordance with the degree of training of the individual, which is an obstacle to mass use in treatment (and / or and prevention) with hypercapnic exposure along with hypoxic stimuli and training of the respiratory muscles due to a violation of the fundamental principle of training - the gradual increase in load from training to training as the degree of training increases.

 The task to which the invention is directed is to create an individual respiratory simulator equipped with tools that can smoothly change the complex training load in terms of inhalation-expiration resistance and degree of hypercapnia - hypoxia of the inhalation medium in full accordance with the individual's fitness level.

 The problem was solved by the applicant as follows, namely: an individual respiratory simulator containing an external vessel with openings for communication with the surrounding atmosphere and for a breathing tube connected to an internal chamber having openings in the lower part and placed in a middle vessel made with an opening at the top for communication with the environment of the external vessel, the following significant distinguishing features have been introduced according to the invention, namely: means have been introduced into the simulator for separating the fraction of used about the volume of the external vessel and means for changing the size of the area of the orifice of the holes in the lower part of the inner chamber.

 In addition, newly introduced means for separating a fraction of the used volume of the external vessel can be made in the form of axial movement and fixation of the transverse septum adjacent to the inner surface of the outer vessel and to the outer surface of the middle vessel.

 In addition, newly introduced means for separating a fraction of the used volume of the external vessel can be made in the form of at least one inflatable container of elastic material placed between the outer surface of the middle vessel and the inner surface of the external vessel.

 In addition, newly introduced means for changing the size of the orifice of the holes in the lower part of the inner chamber can be made in the form of two mutually movable parts of the inner chamber - one part - a glass with a continuous bottom and holes in the form of slots in the side wall, mounted axially movement and rotation on another part - made tubular and open from below the housing of the inner chamber.

 In addition, newly introduced means for changing the size of the bore of the holes in the lower part of the inner chamber can be made in the form of three parts of the inner chamber - one part - having holes in the form of longitudinal slots at the bottom open end, the inner chamber body is made in tubular form on which the second part is installed from the lower end - a blind cover, and the third part is mounted on the outside of the case - a ring with the possibility of axial movement and fixation.

 In addition, when performing newly introduced means for changing the size of the orifice of the openings in the lower part of the inner chamber in the form of a cup with a continuous bottom and openings in the form of slots in the side wall, which is axially movable, consisting of two mutually movable parts of the inner chamber on the other side, made up of a tubular housing and an open bottom housing of the inner chamber, the housing of the inner chamber can be made with a thrust element in the form of a protrusion interacting with a reciprocal screw the new surface of the element made near the glass.

 The introduction of means for separating the portion of the test volume of the external vessel (changing the volume used affects the degree of hypercapnia along with hypoxia of the inhalation medium) and means for changing the bore of the holes in the lower part of the inner chamber (which affects the resistance to inhalation-exhalation) allows you to individually change the value of the complex training effects on the respiratory muscles and the whole body hypercapnic together with hypoxic stimuli in full accordance with the individual's fitness.

 In FIG. 1 shows a general view of an individual respiratory simulator with the implementation of means for separating a fraction of the used volume of the external vessel in the form of a transverse partition and means for changing the size of the passage area of the holes in the lower part of the inner chamber in the form of two mutually movable parts of the inner chamber (when the transverse partition is positioned, in which the fraction of the used volume of the external vessel is minimal, and with the relative position of the two parts of the inner chamber, such that the maximum area di passage section of the openings in the bottom of the inner chamber).

 In FIG. 2 shows a general view of a simulator identical to the simulator shown in FIG. 1, but with the position of the transverse partition, in which the fraction of the used volume of the external vessel is maximum and with the relative position of the two parts of the inner chamber such that the minimum passage area of the openings in the lower part of the inner chamber is minimal.

 In FIG. 3 shows a general view of the simulator with the implementation of means for separating the fraction of the used volume of the external vessel in the form of an inflatable container made of elastic material and means for changing the size of the bore of the openings in the lower part of the inner chamber in the form of a three-part inner chamber (with the largest volume of the inflatable container and, accordingly, the minimum fraction of the used volume of the outer vessel and with the relative position of the three parts of the inner chamber, such that the maximum value of the passage area I have holes at the bottom of the inner chamber).

 In FIG. 4 is a general view of a simulator identical to the simulator shown in FIG. 3, but with a minimum volume of the inflatable tank and a minimum size of the area of the passage section of the holes in the lower part of the inner chamber.

 The individual respiratory simulator contains an external vessel 1, consisting of a body 2 and a cover 3, in which an opening 4 is made for communication with the surrounding atmosphere and an opening 5 for a breathing tube 6 connected to an internal chamber 7 having openings 8 in the lower part, placed in the middle vessel 9. Vessel 9 consists of a housing 10 and a cover 11 made with an opening 12 at the top for communication with the environment of the external vessel 1. Means for separating a fraction of the used volume of the external vessel 1 can be made: or (see Figs. 1 and 2) form of having the axial movement and fixation (in this case, due to interference with elastic deformation) of the transverse septum 13 adjacent to the inner surface of the outer vessel 1 and to the outer surface of the middle vessel 9; or in the form of at least one container, in this case an inflatable container 14 (see FIG. 3 and FIG. 4) of elastic material, for example, rubber, placed between the outer surface of the middle vessel 9 and the inner surface of the outer vessel 1. Capacity 14 equipped with a valve (not shown) to change its volume. Thus, means for separating a fraction of the used volume of the external vessel, based on the exemplary embodiments of FIG. 1 and 3, can be performed constructively in different ways: either in the form of a partition 13, or in the form of a container 14 (containers), and at the same time serve to perform the same function with the same design of the other parts of the simulator. Means for changing the size of the bore of the holes 8 in the lower part of the inner chamber 7 can be made in the form of: or (see Figs. 1 and 2) consisting of two mutually movable parts of the inner chamber - one part - a glass 15 with a continuous bottom and with holes 8 in the form of slots made in the side wall of the glass 15, which is mounted with the possibility of axial movement and rotation on the other part - made tubular and open from the bottom of the housing 16 of the inner chamber 7. The housing 16 can be made with a stop element in the form of a protrusion 17, interacting with the reciprocal screw surface 18 of the element 19, made at the glass 15; or (see Figs. 3 and 4) consisting of three parts of the inner chamber 7, of which one part has openings 8 in the form of longitudinal slots at the bottom open end, of a tubular shape 20, on which the second part is installed from the lower end - a blind cover 21, and the third part is mounted on the outside of the housing 20 — the ring 22, which has the possibility of axial movement and fixation (in this case, due to the interference from elastic deformation).

 The individual respiratory simulator is used as follows.

 The positive effect of respiratory gymnastics using the proposed individual respiratory simulator is based on the use of: the well-known therapeutic and prophylactic effect of the hypoxic-hypercapnic inhalation medium formed in the proposed simulator during the individual's pendulum breathing through the simulator, i.e. in a semi-closed system, the lungs of an individual are a simulator (having an opening for communication with the surrounding atmosphere); arising simultaneously in the simulator of resistance to inhalation-exhalation, training the respiratory muscles.

 Because The individual respiratory simulator is designed for training exposure with hypercapnic along with hypoxic stimuli and at the same time training of the respiratory muscles, then through the simulator, the level of hypercapnia along with the level of hypoxia of the inhalation medium obtained directly inside the simulator and the level of resistance to inhalation - expiration will undergo changes during the training. For each individual workout, the level of hypercapnia together with the level of hypoxia of the inhalation medium can be set within the limits of: hypercapnia - from 0.5 to 7% of carbon dioxide in the inhalation medium; hypoxia - by 5 - 25% reduced oxygen content in the inhalation medium compared with atmospheric air, depending on the simulator setting according to the fraction of the volume of the external vessel used; the inhalation-exhalation resistance can be changed from several tens of millimeters of water to several hundred millimeters of water, depending on the tincture of the simulator according to the size of the passage area of the openings in the lower part of the inner chamber.

 At the beginning of the training, i.e. Before the first trainings, it is necessary to adjust the simulator so that during the training there is minimal hypercapnia, hypoxia and resistance to inhalation-expiration, for which a minimum proportion of the used volume of the external vessel is set to the maximum size of the passage area of the openings in the lower part of the inner chamber. To do this, install the partition 13 in its highest position (see Fig. 1) or (see Fig. 3), increase the volume of the tank 14 to the maximum size; the glass 15 is shifted (see FIG. 1) to the lowermost position along the housing 16, for which they use the possibility of turning the housing 16 with the sliding of the protrusion of the reciprocal screw surface 18 of the element 19 of the glass 15 or (see FIG. 3) the ring is transferred to the extreme upper position 22.

 After adjustment (described above), the simulator is used as follows: the individual produces pendulum breathing through the simulator, which together with the individual's lungs forms a semi-closed system. Further, the description of the formation of hypercapnic-hypoxic environment for breathing is conditionally given separately from the description of the formation of resistance to inhalation-exhalation. In practice, there is a simultaneous occurrence of these interrelated processes in the simulator. With each exhalation, the gas mixture exhaled by an individual having a low oxygen content and a high carbon dioxide content passes from the individual’s lungs through the breathing tube 6, chamber 7, openings 8, vessel 9, opening 12 and enters an external vessel 1 from which initially the air there is displaced through the opening 4. With each inhalation, atmospheric air penetrates through the opening 4 into the vessel 1, which contains a medium with a high content of carbon dioxide and a low oxygen content, increasing the oxygen content and decreasing the carbon dioxide content, while the medium with a high carbon dioxide content and a low oxygen content enters through the opening 12, the vessel 9, the openings 8, the chamber 7 and the breathing tube 6 into the lungs of the individual. With each inhalation-exhalation cycle through the simulator, the carbon dioxide content in the inhalation medium increases, while the oxygen content decreases and after about 2 to 3 minutes the maximum volume for the external vessel used is hypercapnia and hypoxia of the inhaled medium, the levels of which remain for the rest of the training , the total duration of which should be from 15 to 30 minutes.

 In the first trainings, the middle vessel 9 is left empty to ensure minimal pressure on the respiratory muscles due to minimal resistance to inhalation-expiration; before subsequent training, a small amount of liquid (distilled or boiled water) is poured into the middle vessel to a liquid level 2 to 3 mm higher the upper edge of the holes 8. The presence of fluid increases the load - resistance to inhalation-exhalation to values that are training for the respiratory muscles after the growth of fitness that occurred during the first training, when the middle vessel 9 was left empty. Load - resistance to inhalation-exhalation in the presence of fluid is the following: when inhaling, the fluid is sucked into the chamber 7 from the vessel 9, passing through the openings 8, and there is a dynamic hydraulic back pressure (which is greater, the smaller the value of the passage section of the holes 8 is set and the more vigorous inspiration, i.e. faster fluid flow through the holes 8). Then, when the liquid level in the chamber 7 is set higher than the liquid level in the vessel 9, with a further inhalation, it sparges through the openings 8, while overcoming the following resistances: resistance equal to the height of the water column as the difference in levels in the chamber 7 and vessel 9, as well as resistance, which takes place as a dynamic backpressure, arising as a reaction during the flow of a gas medium through openings 8. Upon exhalation, the liquid is pushed out of the chamber 7 into the vessel 9, passing through the openings 8, and a dynamic hydraulic backpressure (which is greater, the smaller the size of the passing section of the holes 8 is established and the more vigorously the inhalation takes place (i.e., the faster the fluid flow through the holes 8). Then, when the liquid level in the vessel 9 is higher than the liquid level in the chamber 7, the gas medium during further exhalation sparges through openings 8, and the following resistances are overcome: resistance equal to the height of the water column as the difference in levels in the vessel 9 and chamber 7, as well as the resistance that occurs a dynamic back pressure that occurs as a reaction while flowing a gaseous medium through the openings 8.

 In the continuation of the training, it is necessary to increase, as the individual is trained, hypercapnia, hypoxia of the inhalation medium and resistance to inhalation-expiration, for which, from training to training, immediately before training, the proportion of the used volume of the external vessel is increased (compared to the position that took place at the previous training) 1 and reduce the size of the passage area of the holes 8 in the lower part of the chamber 7. To do this, install the partition 13 lower and lower or reduce the volume of the tank 14; the glass 15 is displaced along the body 16, closing the holes 8 last (for which they use the possibility of turning the body 16 with the sliding of the protrusion 17 along the counter screw surface 18 of the element 19 of the glass 15); or move ring 22 lower and lower, partially overlapping more and more holes 8 (see Figs. 2 and 4).

 Sources of information.

 1. Patent GDR N 55757, CL A 61 M 15/00, 1967.

 2. USSR patent N 1790417, cl. A 61 M 15/02, publ. 01/23/93, bull. N 3.

Claims (6)

 1. Individual respiratory simulator containing an external vessel with openings for communication with the surrounding atmosphere and for a breathing tube connected to an internal chamber having openings in the lower part and placed in a middle vessel made with an opening at the top for communication with the environment of the external vessel, characterized in that means have been introduced into the simulator for separating a fraction of the used volume of the external vessel and means for changing the size of the passage area of the openings in the lower part of the inner chamber.  2. The simulator according to claim 1, characterized in that the means for separating a fraction of the used volume of the outer vessel are made in the form of axial movement and fixation of the transverse septum adjacent to the inner surface of the outer vessel and the outer surface of the middle vessel.  3. The simulator according to claim 1, characterized in that the means for separating a fraction of the used volume of the external vessel is made in the form of at least one inflatable container of elastic material placed between the outer surface of the middle vessel and the inner surface of the external vessel.  4. The simulator according to claim 1, characterized in that the means for changing the size of the bore of the holes in the lower part of the inner chamber are made in the form of two mutually moving parts of the inner chamber - one part - a glass with a continuous bottom and holes in the form of slots in the side wall installed with the possibility of axial movement and rotation on another part - made and open from below the housing of the inner chamber.  5. The simulator according to claim 1, characterized in that the means for changing the size of the bore of the holes in the lower part of the inner chamber are made in the form of three parts of the inner chamber - one part having openings in the form of longitudinal slots at the open end of the tubular inner chamber the form on which the second part is installed from the lower end is a blind cover, and the third part is mounted on the outside of the body - a ring with the possibility of axial movement and fixation.  6. The simulator according to claim 4, characterized in that the housing of the inner chamber is made with a thrust element in the form of a protrusion interacting with the reciprocal screw surface of the element made near the glass.

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