RU112044U1 - SIMULATOR INHALATOR - Google Patents

Abstract

1. A simulator-inhaler containing a glass, inside which an inner chamber is coaxially installed, and a breathing tube connected to the inner chamber, while the glass is made with the possibility of filling with a medicinal preparation, characterized in that it additionally contains a thermos-stand made with the possibility of maintaining the required temperature of the medicinal product when filling the thermos-stand with hot liquid, in the inner cavity of the thermos-stand there are protrusions for centering and stopping the glass, while the glass contains a lid, a protrusion-stop that interacts with the protrusion of the thermos-stand, a protrusion-regulator made in in the form of a sector, and a retainer protrusion made with the possibility of interacting with the petal protrusion of the inner chamber, the inner chamber is configured to adjust the pressure, contains a perforated nozzle and is installed in the glass in such a way that the protrusion-regulator of the glass coincides with one of the sectors of the perforated nozzle this The breathing tube is made up of two tubes connected to each other by means of an adapter and is connected to a mouthpiece, to which a device for breathing through the nose can be connected using a connecting device. ! 2. A simulator-inhaler according to claim 1, characterized in that the device for breathing through the nose is made in the form of elements with holes, wherein the elements are displaced relative to the center of the device, and the centers of the holes are displaced relative to the centers of the elements. ! 3. A simulator-inhaler according to claim 2, characterized in that the device for breathing through the nose is configured to change the distance between its elements.

Description

This useful model relates to the field of medicine, in particular, to devices that allow training of the respiratory system and therapeutic respiration, which increases the level of carbon dioxide in the blood, as well as for the administration of drugs during inhalation, and can be used to prevent and treat various diseases, to increase the body's resistance to adverse environmental factors, as well as the expansion of the physical, immune and adaptive capabilities of the body.

In the prior art, an inhaler simulator is known that comprises an external vessel with a lid provided with an opening for inhaling air located in its central part and an internal vessel coaxially mounted inside it, at the bottom of which there are openings placed with a gap relative to the bottom of the external vessel, a breathing tube and air inlets located on the lid, while the inner vessel is made in the form of a glass with a stepped bottom, and on the outer surface of the lid around the hole for inspiration of air is located blunt cylindrical shape, on which the breathing tube is installed, while on the inner surface of the lid there is a means for fixing the position of the inner vessel (Utility model RU No. 42428 U1, class A61M 15/00, 10.12.04).

The disadvantages of the described inhaler-simulator are the complexity of the design of the inner vessel and the inability to regulate the internal volume of the glass.

Closest to the proposed utility model is a Frolov inhaler containing a glass inside which the inner chamber is coaxially mounted and a breathing tube connected to the inner chamber, the glass being made with the possibility of filling with a medicinal product (Copyright certificate SU No. 1790417, class A61M 15 / 02, January 9, 91).

Frolov's inhaler also has a number of significant drawbacks. One of the drawbacks of the described inhaler is the limited functionality due to the lack of means for regulating the load during inhalation and exhalation, which would allow, in accordance with the degree of training of the user, to smoothly change the level of resistance to inhalation-exhalation. Another disadvantage of the Frolov inhaler is its low usability, due to both the complexity of the inhaler assembly and the need for the user to constantly maintain the cap and tube to avoid involuntary extraction of the breathing tube together with the inner chamber and spilling liquid filling the inhaler

These shortcomings reduce the area of use of the inhaler, make it difficult to use with individual inhalations and individual training of the respiratory system.

The technical result of the claimed utility model is to increase the effectiveness of the use of an inhaler simulator due to the possibility of individual inhalation of steam-air mixtures of medical preparations, oil aerosols while maintaining the temperature of the mixtures during the procedure and the possibility of conducting an individual training of the respiratory system with the possibility of selecting the load on the respiratory system and selection of the concentration of O ₂ and CO ₂ necessary for training.

The technical result is achieved by the fact that the claimed simulator-inhaler contains a glass, inside of which an inner chamber is coaxially mounted, and a breathing tube connected to the inner chamber. The glass is made with the possibility of filling with a medicinal product. The inhaler trainer additionally contains a thermos-stand, configured to maintain the required temperature of the medicinal product, when filling the thermos-stand with hot liquid, in the inner cavity of the thermos-stand there are protrusions for centering and stopping the glass, while the glass contains a lid, protrusion-stop, which interacts with the protrusion of the thermos-stand, the protrusion-regulator, made in the form of a sector, and the protrusion-latch, made with the possibility of interaction with the lobe protrusion of the inner chamber, the inner chamber, configured to adjust the pressure, contains a perforated nozzle and is installed in the glass so that the protrusion regulator of the glass coincides with the sector of the perforated nozzle. The breathing tube is made up of two tubes connected to each other by means of an adapter and connected to a mouthpiece, to which a device for breathing through the nose can be connected using a connecting device.

In a preferred embodiment, the structural elements of the simulator-inhaler can be performed as follows:

- a device for breathing through the nose can be made in the form of elements with holes, while the elements are offset relative to the center of the device, and the centers of the holes are offset relative to the centers of the elements;

- also a device for breathing through the nose can be made with the possibility of changing the distance between its elements when rotating them around an axis;

- the lid of the glass can be made with the possibility of regulating the internal volume of the glass;

- the petal protrusion of the inner chamber can be made with holes;

- the walls of the thermos-stand are double, with an air gap between them.

Figure 1 shows a General view of the proposed simulator-inhaler.

Figure 2 presents the upper part of the chamber of the simulator inhaler with a petal protrusion.

Figure 3 presents the base of the glass simulator inhaler.

Figure 4 presents the perforated nozzle of the simulator inhaler.

In accordance with figure 1, the simulator-inhaler contains a cup 10, an inner chamber 9, a breathing tube 4, 6 with an adapter 5, a thermos-stand 12, protrusions 121 for centering and stopping the cup 10, a cover 8 are located in the inner cavity of the thermos-stand 12 , the lid 8 contains an element 7, a protrusion-stop 101, a protrusion-regulator 102, a protrusion-latch 103, configured to interact with the petal protrusion 91 of the inner chamber 9, a perforated nozzle 11. The walls of the thermos-stand 12 are double, with an air gap 13 between them. The glass 10 is made with the possibility of filling with a medicinal product or water 14. The thermos stand 12 is made with the possibility of filling it with hot liquid 15. The breathing tube 4, 6 is made of two tubes connected together by means of an adapter 5 and connected to the mouthpiece 3 for breathing through a mouth to which, through a connecting device 2, a device 1 for breathing through the nose can be connected. The device 1 for breathing through the nose is configured to change the distance "A" between its elements when they rotate around an axis.

Figure 2 presents the upper part of the chamber of the simulator-inhaler with a petal protrusion 91, interacting with the protrusion-latch 103 of the glass 10. The upper part of the chamber of the simulator-inhaler contains holes 92.

Figure 3 presents the base of the glass 10 of the simulator inhaler containing the protrusion stop 101 and the protrusion regulator 102.

Figure 4 presents the perforated nozzle 11 of the simulator-inhaler containing sector 111 with holes and sector 112 without holes.

The simulator-inhaler works as follows.

A glass of 10 is filled with 20-40 ml. the medicinal product 14, the infusion of herbs 14 or water 14. In the glass 10, the inner chamber 9 with the attached nozzle 11 is coaxially installed. The cup 10 is closed by the lid 8. To the inner chamber 9 is attached a breathing tube 4, 6 made of one of two interconnected using an adapter 5 tubes and connected to the mouthpiece 3. Hot water (hot liquid) 15 is poured into the thermos stand 12 along the upper line of the protrusion 121, and then a glass 10 with the previously assembled structure is installed in the thermos stand 12. The device (inhaler simulator) for inhalation and training of the respiratory tract through the mouth is ready for use. For inhalation through the nose, a connecting device 2 is put on the mouthpiece 3 with a device 1 made in the form of elements with holes, the elements being offset from the center of the device 1, and the centers of the holes being offset from the centers of the elements. Then, by rotating the elements of the device 1 around the axis, the distance between them is changed, choosing the optimal distance (gap) "A". After that, the device (simulator-inhaler) for inhalation through the nose is ready for use.

When the device (simulator-inhaler) is in inhaler mode:

Hot water (hot liquid) 15 in the thermos stand 12 maintains the required temperature of the medicinal product 14 in the glass 10. When inhaling through the device (nasal elements) 1 or through the mouthpiece 3 (when inhaling through the mouth), the medicinal product 14 through the sector with openings 111 the perforated nozzle 11 is drawn into the inner chamber 9 and spreads into small drops, forming a pair of therapeutic drug 14 in the stream of inhaled air. The vapor flow of the drug 14 and air through the elements 6, 5, 4, 3 (inhalation through the mouth) or through the elements 6, 5, 4, 3, 2, 1 (inhalation through the nose) enter the respiratory tract.

When the device (simulator-inhaler) is in simulator mode for training the respiratory system:

The thermos stand 12 serves as a support for the stability of the glass 10. Water 14 is poured into the glass 10. A perforated nozzle 11 is attached to the inner chamber 9 (the connection has a fixed position). The inner chamber 9 is coaxially mounted in the glass 10 so that the sector 102 is under the sector 112, which provides the maximum number of openings of the sector 111 of the perforated nozzle 11, and provides the minimum load (pressure) during breathing exercises. When you install the inner chamber 9 relative to the glass 10 at position 2, 3 or 4, 5 (the positions are indicated on the lobe protrusion of the inner chamber 9), the sector with holes 111 is displaced relative to the sector 102, which reduces the number of open holes in the sector 111 that allow water 14 and accordingly changes (increases depending on the selected position) the load on the respiratory system.

When inhaling, water 14 passing through the nozzle 11 creates a load on the respiratory system. When you exhale, the exhaled air passing back through the elements 3, 4, 5, 6, 9, 11 is squeezed out into the glass 10, water with air strikes the lobe protrusion 91 of the inner chamber 9. The air goes around the lobe protrusion 91 and passes through the holes 92 and the lid opening 8 into the atmosphere, and water drops 14 return to the bottom of the glass 10, which ensures that there is no water in the stream of exhaled air beyond the borders of the glass 10. The absence of water loss 14 during breathing exercises guarantees a constant and stable load on the respiratory system during training. When inhaled, the above design preserves the therapeutic drug 14.

The lid 8 is configured to attach to the glass 10 and provide a semi-enclosed space using the element 7. The lid 8 is formed by two hollow cylindrical elements and an element 7 (partition), which divides the lid 8 into two parts that are not equal in volume. In this case, the lid 8 can be attached to the glass 10 of any of two parts, which makes it possible to change the internal space formed by the lid 8 and the glass 10. Thus, with a different position of the element 7, either the maximum or minimum internal volume of the glass 10 is provided.

When inhaling and exhaling through the device, i.e. when conducting breathing exercises during the second and subsequent breaths, the patient uses the previously exhaled mixture during inspiration, which ensures a decrease in the amount of oxygen O ₂ and an increase in the amount of carbon dioxide CO ₂ in the inhaled mixture.

The ability to change the internal volume of the glass 10 using the cover 8 allows you to adjust the concentration of oxygen O ₂ and carbon dioxide CO ₂ in the inhaled mixture during breathing exercises.

Thus, the inhaler simulator allows individual inhalation of steam-air mixtures of medicinal preparations, oil aerosols while maintaining the temperature of the mixtures during the procedure, as well as individually conducting respiratory system training with the possibility of selecting the load on the respiratory system and selecting the concentration of O ₂ and CO ₂ , which contributes to both treatment and prevention and prevention of diseases and stresses, rehabilitation and recovery in case of adverse (including radiation) environmental and other factors.

Claims (6)

1. The inhaler simulator containing a glass, inside of which an inner chamber is coaxially mounted, and a breathing tube connected to the inner chamber, the glass is made with the possibility of filling with a medicinal product, characterized in that it further comprises a thermos-stand made with the possibility of maintaining the required temperature of the medicinal product when filling the thermos-stand with hot liquid, in the inner cavity of the thermos-stand there are protrusions for centering and stopping the glass, while contains a cover, a protrusion-stop, which interacts with the protrusion of the thermo-stand, the protrusion-regulator, made in the form of a sector, and the protrusion-latch made with the possibility of interaction with the petal protrusion of the inner chamber, the inner chamber is configured to adjust the pressure, contains a perforated nozzle and installed in the glass so that the protrusion-regulator of the glass coincides with one of the sectors of the perforated nozzle, while the breathing tube is made of one of two interconnected schyu tubing adapter connected to a mouthpiece and to which via a connecting device can be connected to the device for breathing through the nose. 2. The inhaler simulator according to claim 1, characterized in that the device for breathing through the nose is made in the form of elements with holes, while the elements are offset from the center of the device, and the centers of the holes are offset from the centers of the elements. 3. The inhaler simulator according to claim 2, characterized in that the device for breathing through the nose is configured to change the distance between its elements when they rotate around an axis. 4. The simulator-inhaler according to claim 1, characterized in that the lid of the glass is made with the possibility of regulating the internal volume of the glass. 5. The inhaler simulator according to claim 1, characterized in that the petal protrusion of the inner chamber is made with holes. 6. The inhaler simulator according to claim 1, characterized in that the walls of the thermos-stand are double with an air gap between them.