RU2177334C1 - Apparatus for forming biologically active breathing medium from expired and atmospheric air - Google Patents

Abstract

FIELD: medical equipment. SUBSTANCE: apparatus has external vessel with openings for communication with atmosphere and for breathing tube connected to internal chamber. Internal chamber has continuous bottom, side holes arranged in chamber lower part, and devices for changing effective area of holes. Internal chamber is positioned in intermediate vessel equipped with hole arranged in its upper part and adapted for communication with internal vessel medium. Device for defining required volume of external vessel is positioned in external vessel and is made in the form of transverse partition wall which is positioned for axial displacement and may be fixed in predetermined position. Partition wall adheres to internal surface of external vessel and to external surface of intermediate vessel. Apparatus is equipped with device for forming in internal vessel of atmospheric and expired air flows and guiding these flows to transverse partition wall. The latter is formed by two concave surfaces with arced section. Concave surfaces joint place is directed inside used share of cavity defined by partition wall of external wall. Apparatus of such construction allows bioactive breathing medium to be generated from expired and atmospheric air and carbon dioxide and oxygen content to be regulated. EFFECT: increased efficiency and improved adaptability and compensatory capacities of organism. 5 cl, 8 dwg

Description

 The invention relates to apparatus for forming a bioactive respiratory environment from exhaled and atmospheric air with the ability to control the content of carbon dioxide and oxygen and can be used to implement methods of increasing the adaptive and compensatory capabilities of the body due to the normalization of homeostasis in terms of the gas composition of arterial blood by carbon dioxide.

 A known apparatus for the formation using carbon dioxide of exhaled air and atmospheric air of a bioactive respiratory environment (with a high content of carbon dioxide) (see ed. Certificate of the USSR N 1600784, M. class. A 61 M 16/00, publ. 23.10.90 Bulletin No. 39) containing a mask and a housing with a hole for connecting to the atmosphere, which is equipped with a carbon dioxide filter having adsorption and desorption properties and containing inclusions of heat-resistant material, while the walls of the housing are made of heat-insulating material. The carbon dioxide filter has properties that ensure the absorption (adsorption) of carbon dioxide from the air saturated with the latter, and the release of carbon dioxide (desorption) when passing through the air filter without carbon dioxide. At the beginning of the session, the filter absorbs (absorbs) carbon dioxide and accumulates heat from the exhaled air. When the moment of saturation with carbon dioxide and at the same time heating of the filter is reached, the desorption process begins, so that carbon dioxide emitted by the filter enters the inhaled air. The value of the carbon dioxide concentration during the session is determined by constant structural data: dimensions, the relative number of inclusions from the heat-intensive material, the degree of adsorption and desorption properties of the filter, and thermal insulation properties.

The disadvantage of this apparatus is that a particular apparatus is designed to form a mixture with a strictly defined concentration of CO ₂ , i.e. there is the impossibility of changing the value of the concentration of carbon dioxide in the inhaled air without changing the overall design data of the device: the dimensions of the filter, the number of inclusions of the heat-sensitive material, the properties of the thermal insulation used, the properties of the filter material itself. In addition, the disadvantage is the clearly significant inertia of the apparatus. Apparently, after the start of the breathing session, it does not immediately give out the required gas mixture with a high content of CO ₂ , since the process of accumulation of the latter in the filter, as well as heat, is first. It can be a 10-15 minute delay.

 A known apparatus for the formation of a bioactive respiratory environment (with a high content of carbon dioxide) from exhaled and atmospheric air (see ed. Certificate of the USSR N 1607817, M. class. A 61 M 16/00, publ. 23.11.90, bull. N 43), containing as a means of contact with an individual a mask, a single channel of inspiration and expiration in the form of a pipe connected at one end to a mask, and at the other end to a breathing bag. The pipe is made with a hole in the wall for communication with the atmosphere, equipped with a damper and a scale, which should act as a stabilizer of the composition and temperature of the inhaled gas mixture.

 Since atmospheric air is added to the previously exhaled air coming from the breathing bag, immediately in front of the mask, the apparatus has a drawback - it is not ensured within acceptable limits for the composition of the gas mixture according to carbon dioxide given on the scale available for the apparatus, since when breathing through this apparatus the composition of the gas mixture is very dependent on the intensity of respiration, and the latter, firstly, is different for different individuals; secondly, the intensity of breathing during a breathing session with a mixture with a high content of carbon dioxide reflexively increases in all individuals; thirdly, there is a different degree of reflex response to breathing of different individuals with the same hypercapnic mixture (i.e. with a high content of carbon dioxide) in the mixture directly during the session, i.e. the degree of reflex enhancement of ventilation of the lungs (external respiration) can vary greatly.

 Known for the closest in technical essence adopted as a prototype apparatus for the formation of a bioactive respiratory environment from exhaled and atmospheric air (see RF patent N 2118542, M. class. A 61 M 16/00, publ. 10.09.98, bull. N 25 ) containing an external vessel with openings for communication with the surrounding atmosphere and for a breathing tube connected to an internal chamber having a continuous bottom, side openings in the lower part, means for changing the area of their passage section and placed in a middle vessel made with an opening in the upper part d For communication with the environment of the external vessel, equipped with means for separating a fraction of the used volume of the external vessel in the form of axial movement and fixation of the transverse partition adjacent to the inner surface of the outer vessel and the outer surface of the middle vessel.

 The undoubted advantages of this apparatus are, firstly, the initial formation of a bioactive gas medium in a special container (external vessel) and the subsequent provision of the prepared medium to the individual through the breathing tube (this helps to eliminate the stability interference to the composition of the gas medium due to changes in the individual’s breathing intensity); secondly, the device is a specially designed device for breathing with the device - ways to increase the adaptive and compensatory capabilities of the body, for which the device has the functions of changing the loads on the content of carbon dioxide, oxygen and resistance to inhalation-exhalation.

 There is one very specific feature that manifests itself in the process of breathing (4-8 months) as a natural property of the individual-individual apparatus system (formed during the so-called "pendulum breathing" of an individual through an individual apparatus), which negatively affects the functioning of the apparatus. Namely, as you progress through the course, the breathing parameters of the individual change in inversely proportional relationship simultaneously with the change in the directly proportional relationship of the main parameter - the working volume of the individual apparatus. It means that as an individual takes a course of breathing with a bioactive respiratory medium (4-8 months) with increasing carbon dioxide content in the medium (from 0.3 to 3-4%), a regular decrease in the intensity of external breathing. MOD (minute volume of breathing) is reduced by 3-4 times (at rest from 8-12 to 3-4 liters per minute); in the apparatus, at the same time, the working volume is increased (from 0.5 liters to 1.5-2.5 liters, i.e., 3-5 times) to ensure an increase in carbon dioxide content in the bioactive respiratory environment. So, taking into account the totality of the effects of the described processes, as you progress through the course, there is a multiple increase in the level of interference to the proper process of formation in the apparatus of a bioactive respiratory environment with the required gas composition.

 The disadvantage of this apparatus is that the design does not provide funds for compensation (leveling) of this circumstance.

 A disadvantage inherent in the known apparatus itself is the fact that the increase in carbon dioxide concentration is inadequately small in comparison with the increase in the volume of the used part of the external vessel, because in the known device, as the partition moves maximally, the used part of the external vessel increases. the conditions for the formation of a gaseous medium are getting worse, because in the known apparatus the openings in the caps of the outer and middle vessels are adjacent and, moreover, are located opposite each other uga, so that gas exchange is advantageously short path between the holes, so that one obtains the following: the amount used of the outer vessel used is insufficient for forming a gas mixture.

 In addition, the disadvantage is that it is not entirely possible that the stability of the gas composition of the formed gas environment can be influenced by a factor of different intensities of the individual’s external respiration, since the exchange between the closely spaced openings mentioned above leads to the incomplete use of the used part of the external vessel as a “buffer space”.

 The problem solved by the invention is the creation of an apparatus in which: negatively acting circumstances are compensated (leveled out) for the formation of a gaseous medium in the apparatus in the form of a natural decrease in the individual’s breathing intensity as the breathing rate is carried out, provided that the apparatus’s working volume is simultaneously increased; Compensated (leveled) interference to the formation in the apparatus of an environment with a gas composition that is strictly adequate to the volume of the used part of the external vessel; the influence of a factor in changing the respiratory rate of an individual on the stability of the gas composition of the medium for any specific working volume of the apparatus is excluded.

 The problem is solved as follows. In the apparatus for forming a bioactive respiratory environment from exhaled and atmospheric air, containing an external vessel with a lid, with at least one hole for communication with the surrounding atmosphere and with a hole for the breathing tube connected to the inner chamber having a continuous bottom, side holes in the bottom parts, means for changing the area of their bore and placed in the middle vessel with a lid, with at least one hole in the upper part for communication with the environment of the external vessel, in which The means for separating the fraction of the used volume of the outer vessel 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 have introduced significant distinguishing features, namely the aforementioned openings for communication with the surrounding atmosphere and the environment of the external vessel made in the form of means for the formation in the outer vessel of jets of atmospheric and exhaled air and directing them to the transverse partition.

 In addition, the means for forming jets can be made in the form of nozzles tapering towards the exit into the cavity of the external vessel in the caps of the outer and middle vessels, and in addition, the axis of the nozzles can be located along the helical lines of the right direction in the cover of the external vessel and along the helical lines of the left direction in the lid of the middle vessel.

 In addition, the means for forming jets can be made in the form of newly provided slots between the inner surface of the outer vessel and its lid, as well as the outer surface of the middle vessel and its lid, and, in addition, the transverse septum from the side facing the inside of the lobe cavity the volume of the external vessel used can be formed by two concave arched cross-sectional surfaces, the junction of which is directed inside the cavity of the fraction of the volume of the external vessel used.

 Providing the apparatus with means for forming jets of atmospheric and exhaled air in the outer vessel and directing them to the movable partition solves the problem, since interference with the formation of the gaseous medium, which has various reasons listed above, is eliminated. Directional jets from nozzles or slots easily reach the movable partition, no matter what level it is, at any observed intensity of the individual’s external respiration. Thus, the maximum possible degree of use of the working volume of the external vessel is achieved, no matter how large it is, both as a means for forming a gaseous medium (which gives full adequacy of the composition of the gaseous medium to the established working volume), and as a "buffer space" ( which completely excludes the influence of the factor of changes in respiration intensity on the stability of the gas composition of the medium at any established position of the septum in the working volume of the apparatus) Arrangement of nozzles directed to the partition along helical lines; or the use of a curved profile of the partition in the presence of gaps makes it possible to obtain increased stability of the parameters of the process of formation of a gas medium due to additional mixing of gases inside the working volume of the apparatus.

 In FIG. 1 shows an apparatus where, as means for forming jets of atmospheric and exhaled air in an outer vessel and directing them to the transverse baffle, there are nozzles in the caps of the outer and middle vessels.

 In FIG. 2 shows a section along the circumference of the location in the cover of the outer vessel of the nozzles, the axes of which are directed along the helical lines of the right direction.

 In FIG. 3 shows a section along the circumference of the location in the lid of the middle vessel of the nozzles, the axes of which are directed along the helical lines of the left direction.

 In FIG. 4 shows an apparatus with slots provided between the inner surface of the outer vessel and its lid and the outer surface of the middle vessel and its lid, which are means for forming jets of atmospheric and exhaled air in the outer vessel and directing them to the transverse partition.

 In FIG. Figure 5 shows a schematic picture of the functioning of the inhalation means in the form of nozzles forming air jets in the outer vessel and directing them to the transverse septum.

 In FIG. Figure 6 shows a schematic picture of the functioning on the exhale of means in the form of nozzles forming jets of exhaled air in the outer vessel and directing them to the transverse septum.

 In FIG. 7 shows a schematic picture of the functioning of the inhalation means in the form of gaps forming jets of atmospheric air in the outer vessel and directing them to the transverse septum.

 In FIG. 8 shows a schematic picture of the functioning on the exhale of means in the form of gaps, forming in the external vessel jets of exhaled air and directing them to the transverse septum.

 The apparatus for forming a bioactive respiratory environment from exhaled and atmospheric air contains an external vessel 1 with holes for communication with the surrounding atmosphere, this function being performed either by nozzles 2 (see Fig. 1) in the cover 3 of external vessel 1, or by slots 4 (see Fig. 4) between the surface of the external vessel 1 and its cap 3. Nozzles 2 (see Fig. 1) or slots 4 (see Fig. 4) are means for the formation (by inspiration by an individual) in an external vessel 1 of atmospheric jets air (see Fig. 5; 7) and their directions to the transverse partition 5, mounted in the outer vessel 1 with the possibility of axial movement and fixation due to the interference created by the elastic deformation of the partition 5, thus serving as a means for separating a fraction of the used volume of the outer vessel 1. Nozzles 2 are made tapering towards the exit to the cavity of the outer vessel 1. Slots 4 are formed due to the presence of ribs 6, on which the lid 3 rests, closing the outer vessel 1 (see Fig. 4). The total passage section of the nozzles 2 (or slots 4) is chosen equal to the passage section of the breathing tube 7 passing into the outer vessel 1 through the provided hole in the cover 3. The breathing tube 7 is connected to the inner chamber 8 having a continuous bottom, in this case formed by a plug 9. The chamber 8 has side openings 10 in the lower part, and a ring 11 having the possibility of axial movement and fixation (in this case, due to the interference from the elastic Masons). The inner chamber 8 is placed in the middle vessel 12, made with holes in the upper part for communication with the environment of the outer vessel 1, this function being performed either by nozzles 13 (see Fig. 1) in the cover 14 of the middle vessel 12, or by slots 15 (see Fig. 4) between the outer surface of the middle vessel 12 and its lid 14.

 Nozzles 13 (see Fig. 1) or slots 15 (see Fig. 4) are means for the formation (during exhalation by an individual) in the external vessel of the jets exhaled by the individual air (see Fig. 6; 8) and the direction of these jets to the transverse baffle 5. Nozzles 13 are made tapering towards the exit to the cavity of the external vessel 1. The slots 15 are formed due to the presence of ribs 16, on which the cover 14 rests, closing the middle vessel 12. The total passage section of the nozzles 13 (or slots 15) is chosen equal to the bore of the breathing tube 7. The axis of the nozzles 2 (see Fig. 2) could ut be located along the helical lines of the right direction, and the axis of the nozzles 13 are located along the helical lines of the left direction (see Fig. 3). In the presence of slots 4 and 15, the transverse partition 5 from the side facing the inside of the cavity of the share of the used volume of the external vessel 1 can be formed by two concave arcuate cross-sectional surfaces 17 and 18, the junction 19 of which is directed inside the cavity of the share of the used volume of the external vessel 1 ( see Fig. 4).

 An apparatus for forming a bioactive respiratory environment from exhaled and atmospheric air (hereinafter referred to as the apparatus) is used as follows.

 Essentially, the apparatus is a device for implementing methods of increasing the adaptive and compensatory abilities of the body by ensuring the normalization of vital indicators of homeostasis in terms of the arterial blood gas composition of carbon dioxide, i.e. elimination of hypocapnia - the pathogenetic state of the body, resulting in chronic tissue hypoxia, corresponding to the last severe energy starvation (with a 20-fold drop in macroerg production) of billions of cells, leading to the appearance of pathologies - coronary heart disease, vegetative-vascular dystonia, hypertension, insomnia, migraines, constipation, gastric ulcer, ulcerative colitis, diabetes mellitus (not insulin-dependent), obesity, infertility, impotence, osteochondrosis, etc. The naturally determined elimination of the pathogenetic state - hypocapnia (and with it chronic tissue hypoxia and energy hunger) is possible by reducing the MOD (minute respiratory volume) by 3-4 times from the usual 8-12 liters per minute to 3-4 liters per minute (at rest). This effect is achieved as a result of the use of a 4-8-month course of daily breathing exercises (sessions) through the apparatus for 20-30 minutes with increasing carbon dioxide content as the course progresses and decreasing oxygen in the bioactive respiratory environment, while providing physiologically related with the first type of effect of the increasing training effect on the respiratory muscles, mainly on the diaphragm.

 So, through the apparatus, the following parameters are subject to change during the course: the increase in the content (voltage, partial pressure) of carbon dioxide (increase in hypercapnia); a decrease in the content (voltage, partial pressure) of oxygen (increased hypoxia); increased resistance to inhalation-exhalation.

 For each individual lesson (session), the level of hypercapnia together with the level of hypoxia of the inhalation medium can be set within the limits of: hypercapnia - from 0.3 to 3-4% of carbon dioxide in the inhalation medium; hypoxia - a 5–25% reduced oxygen content in the bioactive respiratory environment compared to atmospheric air, depending on the setting of the apparatus according to the fraction of the volume of the external vessel used; resistance to inhalation-exhalation can be changed from several tens of millimeters of water to several hundred millimeters of water, depending on the tincture of the apparatus according to the size of the orifice in the bottom of the inner chamber.

 At the beginning of the course, i.e. Before the first sessions, it is necessary to configure the device so that during the session there is minimal hypercapnia, hypoxia and resistance to inhalation-expiration, for which the minimum fraction of the used volume of the external vessel 1 and the maximum passage area of the openings 10 in the lower part of the inner chamber are set. To do this, set the partition 5 to its highest position and put the ring 11 into its highest position (see Fig. 4).

 After adjustment (described above), the device is used as follows: the individual, with his nose closed, produces pendulum breathing through the device through the device, which, together with the individual's lungs, forms a semi-closed system. Further, a description of the formation of a bioactive respiratory environment is conditionally given separately from a description of the formation of resistance to inhalation-exhalation. In practice, there is a simultaneous occurrence in the apparatus of these interrelated processes. At each exhalation, the gas mixture exhaled by an individual having a naturally low oxygen content and a high carbon dioxide content passes from the individual’s lungs through the breathing tube 7, the inner chamber 8, the side openings 10, the vessel 12, the nozzle 13 (or slot 15), and the jets created by nozzles 13 (or slots 15) directed to the partition 5 and easily reaching the level of its location, no matter what position it is in (see Fig. 6; 8), enters the outer vessel 1, from which it is displaced into the atmosphere available there initially air through nozzles 2 (or slots 4). With each inhalation, atmospheric air penetrates through the nozzle 2 (or slots 4), creating jets of atmospheric air directed to the partition 5 and easily reaching the level of its location, into the vessel 1, which contains an environment with a high content of carbon dioxide and a low oxygen content. no matter what position it is (see Fig. 5; 7), slightly increasing the oxygen content and decreasing the carbon dioxide content, while the medium with a high content of carbon dioxide and a low oxygen content enters through nozzles 13 (or slits 15) into the vessel 12, through the openings 10 into the chamber 8 and the breathing tube 7 into the lungs of the individual. With each inhalation-exhalation cycle performed through the apparatus, the carbon dioxide content in the inhalation medium increases, and the oxygen content decreases and after about 2-3 minutes, the maximum for this volume fraction of the volume of the external vessel used is hypercapnia and hypoxia of the bioactive respiratory environment, the levels of which all the remaining time of the session is saved, the total duration of which should be from 15 to 30 minutes.

 As the implementation of the means for the formation in the outer vessel 1 jets of atmospheric and exhaled air and directing them to the transverse partition 5 in the form of nozzles 2; 13, the axes of which are directed along helical lines of the right and left directions, respectively, and the implementation of these means in the form of slots 4 and 15 of the transverse septum 5 with concave surfaces 17 and 18 and their interface in dynamics 19 provides additional stabilization of the bioactive respiratory environment by ensuring that the additional function of mixing the gas flows is performed by swirling, or by directing the jets alternately (inhale-exhale) with nozzles, then pos. 2, then pos. 13 along helical lines of different directions, or by turning the jets with concave surfaces then pos. 18, then pos. 17, if the jets alternately (inhale-exhale) form cracks then pos. 4, then pos. fifteen.

 In the first classes, the middle vessel 12 is left empty to ensure minimal pressure on the respiratory muscles due to minimal resistance to inhalation-expiration; before subsequent sessions, a small amount of liquid (distilled or boiled water) is poured into the middle vessel 12 to a liquid level of 2-3 mm above the upper edge of the holes 10. 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 three when the middle vessel 12 was left empty. The load - the resistance to inhalation-exhalation in the presence of fluid is the following: when inhaling, the fluid is sucked into the chamber 8 from the vessel 12, passing through the holes 10, and there is a dynamic hydraulic back pressure (which is the greater, the smaller the position of the ring 11 is set, the passage size of the holes 10 and the more energetically the individual takes a breath, i.e., the faster the flow of fluid through the holes 10). Then, when the liquid level in the chamber 8 is set higher than the liquid level in the vessel 12, the gas medium sparges through the holes 10 with further inspiration, while overcoming the following resistances: resistance equal to the height of the water column as the difference in levels in the chamber 8 and vessel 12, as well as resistance, which takes place as a dynamic backpressure, arising as a reaction when the gas medium flows through the openings 10. When exhaling, the liquid is pushed out of the chamber 8 into the vessel 12, passing through the openings 10, and di amicheskoe hydraulic back pressure (which is the greater, the smaller position of the ring 11 is the quantity the flow cross section than the holes 10 and vigorously carried exhalation individual (i.e., faster fluid flow through the opening 10)). Then, when the liquid level in the vessel 12 is set higher than the liquid level in the chamber 8, the gas medium sparges through the holes 10 upon further exhalation, and the following resistances are overcome: resistance equal to the height of the water column as the difference in levels in the vessel 12 and chamber 8, as well as resistance, which takes place as a dynamic backpressure, arising as a reaction during the flow of a gaseous medium through openings 10.

 In the continuation of the course, it is necessary to increase, as the individual is trained, hypercapnia, hypoxia of the bioactive respiratory environment and resistance to inhalation-expiration, for which, successively from session to session, immediately before the session, the proportion of the used volume of the external vessel is increased (compared to the position that took place in the previous session) 1 and reduce the size of the passage area of the holes 10 in the lower part of the chamber 8. To do this, install the partition 5 lower and lower and move the ring 11 lower and lower, blocking I it is partially more and more holes 10 (see. FIG. 1).

Claims (5)

 1. Apparatus for forming a bioactive respiratory environment from exhaled and atmospheric air, containing an external vessel with a lid, with at least one opening for communication with the surrounding atmosphere and with an opening for a breathing tube connected to an internal chamber having a continuous bottom, side openings in the lower part, means for changing the area of their bore and placed in the middle vessel with a lid, with at least one hole for communication with the environment of the external vessel, in which the means for the proportion of the used volume of the outer vessel 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, characterized in that the aforementioned openings for communication with the surrounding atmosphere and the environment of the outer vessel are made in the form of means for education in an external vessel of jets of atmospheric and exhaled air and their direction to the transverse septum.  2. The apparatus according to claim 1, characterized in that the means for forming jets are made in the form of nozzles tapering towards the exit into the cavity of the external vessel in the caps of the external and middle vessels.  3. The apparatus according to claim 2, characterized in that the axis of the nozzles are located along the helical lines of the right direction in the lid of the outer vessel and along the helical lines of the left direction in the lid of the middle vessel.  4. The apparatus according to claim 1, characterized in that the means for forming jets are made in the form of gaps between the inner surface of the outer vessel and its lid, as well as the outer surface of the middle vessel and its lid.  5. The apparatus according to claim 4, characterized in that the transverse septum from the side facing the inside of the cavity of the lobe of the used volume of the external vessel is formed by two concave curved arched surfaces in the cross section, the junction of which is directed inside the cavity of the lobe of the used volume of the external vessel.

Images