RU2675342C2 - Device for creating a hypercapnia in human - Google Patents

Abstract

FIELD: medical equipment.SUBSTANCE: invention relates to medical equipment field. Device for creating hypercapnia in humans contains a respiratory chamber for the accumulation of carbon dioxide and a breathing tube with a mouthpiece. Respiratory chamber is made in the form of a folding corrugated tank with a variable volume, fixed tightly around the perimeter on the proximal and distal rectangular plates, the base of which is movably mounted on the axis with the possibility of sliding relative to each other. Breathing tube is removable. Plates are provided with openings for the entry of air from the atmosphere into the respiratory chamber when inhaling and exiting the respiratory chamber when exhaling. In one of the plates there is a latch with grooves for fixing the breathing tube and a hole that coincides with the lumen of the inserted breathing tube. Threaded sleeve is fixed on the axis for a fixing nut installed with the possibility of fixing the position of the support plates, and a washer with divisions on it corresponding to the volumes of the breathing chamber.EFFECT: technical result consists in reducing the overall dimensions, weight and cost of the device for obtaining gas mixtures for breathing with different concentrations of carbon dioxide.1 cl, 3 dwg, 1 tbl

Description

The invention relates to medicine, namely to preventive medicine and rehabilitation. The proposed device is used to train the body normobaric gas mixture with a high content of carbon dioxide.

In medical practice, breathing with hypoxic gas mixtures is widely used, which allows to obtain a number of positive physiological reactions: normalizing blood pressure, improving coronary and cerebral blood flow, improving patency, strengthening the body's defenses, etc. (Agadzhanyan N.A., Stepanov O.G. , Arkhipenko Yu.V. Corrective effect of the altered gaseous environment during functional disorders of the digestive system. Maykop: MSTU Publishing House, 2011. - 210 p.). To obtain a hypoxic mixture, various device designs are used.

A device for producing a hypoxic respirable mixture with a low oxygen content (hypoxicator company "Bio-Nova"). However, the device is expensive, has large overall dimensions, large weight (70-80 kg), takes up a lot of area (8 m ² ).

A device is known (MV Dvornikov, VK Stepanov, NI Chernyak et al. Improving the effectiveness of normobaric interval hypoxic therapy by adding carbon dioxide to a hypoxic mixture / In book: Intermittent normobaric hypoxic therapy. Reports of the Academy of Problems of Hypoxia of the Russian Federation. T.Z.M .: PAIMS, 1999. - pp. 89-91), in which, using generators and membranes, different concentrations of carbon dioxide in the inhaled mixture are created. However, the devices used are bulky, stationary and expensive. The latter does not allow to ensure accessibility to the device of the broad masses of the population.

A device (prototype) is known for breathing in a modified gas environment with a high content of carbon dioxide, based on return breathing (RF patent No. 2248812. Device for creating hypercapnia in humans. Authors: Lysenkov SP, Tel L.Z., Agadzhanyan N.A. ., etc.) Due to the accumulation of carbon dioxide in the chamber, the oxygen concentration decreases. Due to this, a hypoxic mixture is created, with an increased concentration of carbon dioxide (hypercapnia). The device comprises a breathing chamber for accumulating carbon dioxide, a breathing tube and a mouthpiece. The camera is made in the form of cylinders with conical bases located one in another and having the ability to move one relative to the other, which allows you to change the volume of the camera. However, this device is large enough, which makes it difficult to operate in non-domestic conditions (travel, business trips, accommodation in a hotel, in a country house, etc.). In addition, the device uses a non-reversible Ambu valve, which leads to a significant increase in the cost of the device.

Known hypercapnicator TDI-02 (analogue) Yu.N. Mishustina (RF patent №2118542. Individual respiratory simulator).

The TDI-02 simulator consists of two cylindrical chambers that enter one another and are filled with water, directly connected to the breathing tube and mouthpiece. The inner chamber has a slotted nozzle with a diaphragm that allows you to adjust the physical load on the body. The whole structure is placed in an external respiratory chamber of variable volume (glass jars of different capacities). An external breathing chamber is necessary to increase the concentration of carbon dioxide and reduce the concentration of oxygen in the inhaled air mixture. According to the attached instructions, the methodology for using the device consists of several stages.

First step. Breathing with minimal stress. When assembling TDI-02, before each lesson, water is not poured into the glass. The diaphragm is mounted on the top of the glass. The top of the camera is lowered to the limit.

If you can not breathe through TDI-02 for 20 minutes without undue effort and discomfort during the first training sessions, you should limit yourself to less time. Constantly from lesson to lesson will increase spontaneously (up to 10 minutes).

When assembling the inner chamber by turning the nozzle, its slots are installed opposite the slot in the housing, that is, so that all the slots are open.

Second phase. When assembling TDI-02, before each lesson, 2 tablespoons of warm boiled water is poured into a glass. All nozzle slots are open (as in step 1). The diaphragm is set in the middle of the height of the glass. The upper part of the external chamber is lowered to the limit.

The third stage. When assembling TDI-02, before each lesson, 3 tablespoons of water is poured into a glass. All nozzle slots are open (as in step 1). The diaphragm is removed from the structure. The top of the camera is lowered to the limit.

The fourth stage is the final one. When assembling TDI-02, before each lesson, 3 tablespoons of water is poured into a glass. The diaphragm is removed from the structure. The upper part of the outer chamber is raised 60 mm in the lower position.

During the fourth stage, it is recommended to gradually increase physical activity. To do this, when collecting the inner chamber by turning the nozzle, first one, then two, and at the end of the stage of five nozzle slots are blocked.

The design of the apparatus assumes the presence of replaceable containers (glass jars of different capacities) filled with water. The device has up to 10 collapsible parts.

However, when using it, a number of disadvantages are revealed:

1. The dimensions of the device are large enough that requires its installation, usually on a table or stand.

2. The device has a sufficiently large number of parts, which complicates their processing.

3. The weight of the device is up to 700 g, which limits its use in travel, business trips, on vacation, when playing sports, etc.

4. The use of the device for the "ordinary" consumer is difficult due to the need to follow numerous instructions (pouring water, adjusting the diaphragm, replacing an external container, etc.).

5. The cost of the device is relatively high.

The aim of this invention is to simplify and create a portable individual device with minimal dimensions, weight and cost, which allows to obtain an inhaled gas mixture with different concentrations of carbon dioxide.

This goal is achieved in that the breathing chamber for the accumulation of carbon dioxide is made of food-grade polyethylene in the form of a folding corrugated container with a variable volume.

"The technical essence of the invention lies in the fact that the device for creating hypercapnia in humans, containing a breathing chamber for accumulating carbon dioxide and a breathing tube with a mouthpiece, characterized in that the breathing chamber is made in the form of a folding corrugated reservoir with a variable volume, fixed tightly around the entire perimeter on the proximal and distal rectangular plates, the base of which is movably fixed on the axis with the possibility of separation relative to each other, while breathing The one-piece pipe is removable, the plates are equipped with openings for air to enter from the atmosphere into the breathing chamber when inhaling and exiting the breathing chamber when exhaling, in one of the platinum there is a latch with slots for fixing the breathing pipe and a hole matching the lumen of the inserted breathing pipe, and the said axis, a sleeve is fixed with a thread for a fixing nut installed with the possibility of fixing the position of the support plates, and the washer with the marks applied on it corresponding to the volumes of the respiratory camera.

The technical result of the invention is the creation of a device with small dimensions, weight and cost, which allows to obtain a gas mixture with different concentrations of carbon dioxide. For the explanation of FIG. 1, 2, 3 shows a general diagram of the device in disassembled and operational condition.

The device consists (Fig. 1, 2, 3) of a breathing chamber made in the form of a folding corrugated reservoir for carbon dioxide storage (1), proximal and distal rectangular support plates (2, 3), the base of which is movably fixed on the axis. This makes it possible to extend the plates relative to each other. In the plate there is an opening (4) for air to enter from the atmosphere when inhaling and an opening (5) with a lock and grooves for ejecting the air mixture when exhaling. The retainer and grooves are designed to fix the breathing tube with a mouthpiece (6). In the working position, the lumen of the pipe and mouthpiece coincides with the lumen of the hole in the plate. The plates are fixed on an axis with a sleeve (7, 8) having a thread for the fixing nut and washer (9) with the marks applied on it, corresponding to the volumes of the breathing chamber.

The device operates as follows. The supporting plates 2, 3 (Fig. 1) are bred on both sides to the required volume (Fig. 2), as evidenced by the divisions on the washer (divisions are pre-calibrated in volume from 500 to 1200 cm ³ ). In this case, the corrugated breathing chamber (1) is expanded to a predetermined volume.

The locking nut (10) during rotation, moving along the thread of the sleeve (7, 8), fixes the position of the support plates (2, 3). A breathing tube (Fig. 3) with a mouthpiece (6) is inserted into the grooves of the retainer (11) so that the hole (5)

coincided with the lumen of the breathing tube (Fig. 3). In this form, the device is ready for use.

A man puts a clothespin on his nose, takes a mouthpiece in his mouth and begins to inhale and exhale. When inhaling, air through the hole (4) enters the respiratory chamber (1) and then through the hole 5 and through the breathing pipe with a mouthpiece (6) into the respiratory tract. When exhaling, the exhaled gas from the respiratory tract through the respiratory mouthpiece (6) enters the chamber (1), and part of it exits through the opening 4 into the atmosphere. At the same time, the concentration of carbon dioxide in the chamber increases with each exhalation (the principle of return breathing).

After the end of the therapy session, the breathing tube with the mouthpiece is removed, the supporting plates are reduced to the center and fixed. In this state, the device occupies a minimum volume and corresponds in shape to a notepad. This allows you to carry it with you, or in a hand luggage.

Control measurements of the carbon dioxide content in the respiratory chamber of the device at a 15 minute session showed results that satisfy the goal in the invention. These data are given in the table.

The ability to metered change the volume of the respiratory chamber allows the device to be used in people (sick and healthy) with various adaptive reserves of the body.

Thus, the proposed device has several advantages over the known:

1. Has small volumes and sizes;

2. Has a low weight (75-80 g);

3. It makes it possible to use the device in various life conditions: on a walk, on a business trip, in the country, etc.

4. Has a low cost.

The medical and social effect of the proposed device lies in the possibility of using it both in patients with various pathologies and in healthy people, including athletes, to improve the adaptive capabilities of the body.

Claims (1)

A device for creating hypercapnia in humans, containing a breathing chamber for accumulating carbon dioxide and a breathing tube with a mouthpiece, characterized in that the breathing chamber is made in the form of a folding corrugated reservoir with a variable volume, sealed tightly around the perimeter on the proximal and distal rectangular plates, the base of which movably fixed on the axis with the possibility of separation relative to each other, while the breathing tube is removable, the plates are provided with With openings for air from the atmosphere into the breathing chamber when inhaling and exiting the breathing chamber when exhaling, in one of the platinum there is a latch with grooves for fixing the breathing tube and a hole matching the lumen of the inserted breathing tube, and a sleeve with a thread is fixed on the axis a fixing nut installed with the possibility of fixing the position of the support plates, and the washer with the marks applied on it corresponding to the volumes of the breathing chamber.

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