RU83421U1 - RESPIRATORY SIMULATOR - Google Patents

Abstract

1. The breathing simulator, made in the form of a mask with inspiratory and expiratory valves and an exhalation resistance force generation unit installed externally in front of the exhalation valve, characterized in that the exhalation resistance force generation unit is configured to consistently form two phases, the first of which is a gradual decrease in exhalation effort from a priori established, and the second - a sharp drop in force to 0 until the end of the exhalation. ! 2. The breathing simulator according to claim 1, characterized in that the unit for generating exhalation resistance forces is made, for example, in the form of a tubular element deformed into a spiral due to a longitudinal elastic insert connected by means of a sleeve to the exhalation valve. ! 3. The respiratory simulator according to claim 1, characterized in that it is equipped with a unit for generating an inspiratory resistance force made in the form of a cylinder, with one end hermetically fastened to the inspiratory valve, and on the other end of which an exhalation resistance force forming unit is fixed with its sleeve, that its deformable tubular element is located inside the cylinder. ! 4. The breathing simulator according to claim 1, characterized in that the mask is equipped with an element for connecting a device for measuring pressure under the mask. ! 5. The respiratory simulator according to claim 1, characterized in that it is equipped with mask fastening elements on the patient's head.

Description

The proposed utility model relates to medical equipment, namely, devices for therapeutic respiration, which can be used both in medical institutions in treatment rooms and by the patient independently, with the consulting support of the attending physician.

Currently, a large number of people are characterized by such negative components of modern life as a lack of physical activity, frequent stress and poor nutrition.

This leads to the fact that almost everyone, starting from the age of 20, has a gradual decrease in the concentration of CO2 in the tissues (hypocapnic shift), as a result of which mainly due to a decrease in oxygen transported by the blood, metabolic and energy processes are disrupted, which leads to 40- 50 years old manifests itself in the form of symptoms of various diseases, such as rhinitis, tracheitis, bronchitis, asthma, pneumonia, vegetative-vascular dystonia, hypertension, etc.

To correct the CO2 content in the body, pharmacological agents, breathing simulators, breathing apparatus, inhaling the gas mixture with a high CO2 content, devices with automated adaptation of the breathing process and objective monitoring of the patient's condition are used.

The last type of devices is device (1), in which objective monitoring of the state of gas exchange function and lungs during training is performed by continuous monitoring of the content of CO2 in exhaled air. The device allows you to automatically adapt to the individual characteristics of the patient’s breathing.

The disadvantage of this device is its high price, overlapping the possibility of its use for the vast majority of potential patients.

There is a well-known affordable breathing simulator (2), which forms during breathing a constant additional resistance on exhalation, which can be adjusted and individually adapted to the patient, creating one degree or another of increasing CO2 concentration to affect the lungs and bronchi.

The disadvantages of this device, despite the possibility of a rapid assessment of the value of additional resistance during exhalation are:

- difficulties in the development of the patient respiratory technology when using the device;

- the need for frequent visits to the doctor to monitor and correct the course of treatment;

- the lack of objective operational assessment of the course of respiratory training in order to avoid relapse;

- lack of self-adjustment of the device to the individual characteristics of the patient;

- the duration of the treatment process;

- low efficiency of hypocapnia correction using the technology of formation of a constant exhalation resistance force.

A very simple and cheap breathing simulator is known (3), which uses the principle of formation of constant additional resistance during exhalation, which increases the concentration of CO2 in the bronchi and lungs, and therefore in the blood.

The disadvantages of this device, despite the general availability for the mass consumer, as well as the above (2), are:

- difficulties in the development of the patient respiratory technology when using the device;

- the need for frequent visits to the doctor for advice on the progress of training and correction of treatment;

- lack of objective operational assessment of the course of respiratory training;

- the impossibility of self-tuning the device to the individual characteristics of the patient.

- the duration of the treatment process.

- low efficiency of hypocapnia correction using the technology of formation of a constant exhalation resistance force.

The breathing simulator (2) was chosen by the author as a prototype of the proposed one, as the closest in technical essence and achieved technical effect.

The task that the author set himself when developing the proposed breathing simulator - capnicator was to increase the simulator's efficiency and, as a result, to reduce the duration of the training course without complicating the simulator design.

This problem is solved in the proposed design of a breathing simulator - capnikator containing a mask with inhalation and exhalation valves, and an exhalation resistance force generating unit installed outside the exhalation valve, configured to consistently form two phases, the first - a gradual decrease in exhalation force from a priori established and the second - a sharp drop in force to 0 until the end of exhalation.

A new significant feature of the breathing simulator is the implementation of the unit for exhalation resistance force formation with the possibility of successive formation of two phases, in the first of which a smooth decrease in exhalation force from a priori set is provided, and in the second, a sharp release of force to 0 until the end of exhalation.

In special cases, the implementation of a breathing simulator:

- the unit for generating the exhalation resistance force is made, for example, in the form deformed due to the longitudinal, elastic insertion into the spiral of a tubular element connected by means of a sleeve to the exhalation valve;

- it is equipped with a unit for generating an inspiratory resistance force made in the form of a cylinder, connected at one end to an inspiratory valve, and at its other end an exhalation resistance generating unit is fixed with its sleeve, so that its deformable tubular element is inside the cylinder;

- the simulator mask is equipped with an element for connecting a device for measuring pressure under the mask.

- it is equipped with mask mounting elements on the patient’s head.

New essential features of a breathing simulator in special cases are:

- the implementation of the node forming the force of resistance to exhalation, for example, in the form deformed due to the longitudinal, elastic insertion into the spiral of a tubular element connected by means of a sleeve to the exhalation valve;

- supplying it with a unit for generating an inspiratory resistance force made in the form of a cylinder, one end hermetically fastened to the inspiratory valve, and on the other end of which an exhalation resistance generating unit is fixed with its sleeve, so that its deformable tubular element is inside the cylinder;

- supplying the simulator mask with an element for connecting a device for measuring pressure under the mask.

- supplying it with mask mounting elements on the patient’s head.

According to the authors, the above new features of the respiratory simulator are significant, because allow you to increase the effectiveness of breathing exercises and reduce training time without complicating the design of the simulator.

This conclusion of the author is confirmed by the centuries-old practice of power martial arts, where when conducting power receptions in the training process and in combat conditions, breathing technology is used similar to the breathing technology implemented in the developed simulator.

The proposed breathing simulator is schematically represented in figure 1 and figure 2, where:

- figure 1 shows a General view of the simulator;

- figure 2 presents the operation diagram, for example, of the unit for exhalation resistance force formation, where: I - the initial position of the tubular element deformed into a spiral before exhaling, II - the type of the tubular element in the middle of the first exhalation phase, III - the type of the tubular element at the beginning of the second expiratory phases.

The respiratory simulator contains a mask 1, fixed to the patient’s head 2 with a retaining element, for example, in the form of a length-adjustable strap 3.

In the mask, an inspiratory valve 4 and an exhalation valve 5 are mounted (as a conventional respirator).

On the valves 4 and 5, outside the mask 1, there are fixed nodes for forming resistance to inspiration 6 and exhalation 7, which can be made, for example, in the form of a sleeve 8 with a tubular element 10 deformed into a spiral due to a longitudinal, elastic insert 9.

Moreover, in the exhalation line, the node 7 is fixed with its sleeve 8 to the valve 5, and in the inhalation line the node 6 is fixed with its sleeve 8 turned 180 degrees inside the connecting pipe 11, fastened to the valve 4.

The simulator can be equipped with a pressure gauge 12, under the mask.

Why in the wall of the mask element 13 is fixed, connected by a rubber hose 14 to the pressure gauge 12.

In the proposed simulator in nodes 6 and 7, bushings 8 with different passage openings can be used, elastic inserts 9 with different degrees of elasticity can be used, and the tubular element 10 can be made of materials with different stiffness and breathability characteristics.

To conduct a healthful breathing course, it is first necessary to consult with the attending physician regarding the regimen of the respiratory procedure and make the appropriate settings, consisting in the selection of the breathing regimen designed for the novice patient.

Setting the breathing simulator for wellness breathing consists in selecting the cross section of the sleeves 8, selecting the necessary stiffness of the insert 9 and the material and length of the tubular element 10 of the nodes 6 and 7, adjusting the mask holding the belt 3 and connecting the pressure gauge 12 through the hose 14 to the element 13.

The choice of the cross section of the tubes 8 is made empirically based on the following rule.

Tube 8 is selected correctly if the patient can maintain pressure when exhaling at least 10 cm of water for several seconds and if he can breathe with the simulator effortlessly for several minutes. Pressure is measured by a manometer 12.

When inhaling, the inspiratory valve 4 is open, the exhalation valve 5 is closed, when exhaling, on the contrary, the exhalation valve 5 is open, the inspiratory valve 4 is closed.

The sequence of stages of inhalation and exhalation in this simulator does not differ from the generally accepted ones and consists in the following.

1. Take a slow and deep breath.

2. Hold the air for 2-3 seconds.

3. Exhalation with resistance - active exhalation with the inclusion of exhalation muscles. Exhale as fully as possible. The abdomen and chest are flattened noticeably.

4. After every 10-20 respiratory cycles, the torn secret is removed, rested and expectorated by forced expiration.

5. When you urge to cough, you can do one to three cough tremors.

6. After several cycles performed (one cycle consists of 10-20 breaths and exhalations and a short pause to remove the secret), take a break to relax, for example in a position that makes breathing easier, or on an inflatable ball.

The methodology of breathing training is described in more detail in (4).

I would like to note that the proposed breathing simulator allows you to conduct training both as a prototype, ensuring constant resistance to breathing, and in accordance with the proposed two phase law of breathing in three versions:

- exhale with a knot of resistance to breathing, inhalation is free;

- inhalation with a knot of resistance to breathing, exhalation is free;

- and inhale and exhale with nodes of resistance to breathing.

Because the work of the breathing simulator is identical both on inhalation and on exhalation; let us consider its work on the example of its work on exhalation.

Unlike the prototype, where the exhalation resistance force depends on the cross-sectional area of the calibrated sleeve and during exhalation it is constant, in the proposed breathing simulator, the resistance force changes according to a certain law provided by the design of the exhalation resistance unit.

In accordance with the selected law, the exhalation in the proposed design of the breathing simulator is divided into two phases (see phases II and III of figure 2):

- the first when the resistance force smoothly decreases from the initial set (when exhaling, the spiral element 10 is gradually unwound and inflated into a cylinder, like an inflatable toy "mother-in-law's tongue" - see phase II of figure 2);

- and the second, when there is a sharp decrease in the exhalation resistance force to 0, which is ensured by a sharp increase in the bore for the air outlet when the spiral of element 10 is completely unwound (see phase III of figure 2).

The operation of elements and components of the device in all three modes is similar.

As already noted, when inhaling, the inspiratory valve 4 is open, the exhalation valve 5 is closed, when exhaling, on the contrary, the exhalation valve 5 is open, the inspiratory valve 4 is closed.

When conducting respiratory training, the doctor-consultant draws the patient's attention to changes in the pressure gauge indicative of an improvement in breathing performance or makes appropriate adjustments to the simulator settings when used improperly.

Currently, the author has verified the simulator’s principle of operation on a prototype, work is underway to test a prototype inspiration and expiration resistance unit based on the design described in the application.

In the manufacture of the author uses general technical materials and commonly used technologies.

For the manufacture of the main part of the resistance unit, the deformable spiral element, variants of using both film and woven materials are possible.

Preliminary test results confirming the technical effect set forth in the application are obtained.

Literature.

1. The device UTRPD-BOS-01 (The device is a simulator for adjusting the parameters of external respiration with biological feedback depending on the content of CO2 in exhaled air).

OOO Marimed, Krasnodar, Vishnyakova St., Building 2

2. PEP devices (Pozitiv Expiratory Pressure). PEP - mask and PEP - system. HTML: // A: \ Flutter.

Breathing simulators with adjustable constant resistance during exhalation and a measuring pressure gauge.

3. Respiratory simulator "Samozdrav" for the correction of hypocapnia.

http://www.med-magazin.ru/products/311/1603/

Claims (5)

1. The breathing simulator, made in the form of a mask with inspiratory and expiratory valves and an exhalation resistance force generation unit installed externally in front of the exhalation valve, characterized in that the exhalation resistance force generation unit is configured to consistently form two phases, the first of which is a gradual decrease in exhalation effort from a priori established, and the second - a sharp drop in force to 0 until the end of the exhalation. 2. The breathing simulator according to claim 1, characterized in that the unit for generating exhalation resistance forces is made, for example, in the form of a tubular element deformed into a spiral due to a longitudinal elastic insert connected by means of a sleeve to the exhalation valve. 3. The respiratory simulator according to claim 1, characterized in that it is equipped with a unit for generating an inspiratory resistance force made in the form of a cylinder, with one end hermetically fastened to the inspiratory valve, and on the other end of which an exhalation resistance force forming unit is fixed with its sleeve, that its deformable tubular element is located inside the cylinder. 4. The breathing simulator according to claim 1, characterized in that the mask is equipped with an element for connecting a device for measuring pressure under the mask. 5. The respiratory simulator according to claim 1, characterized in that it is equipped with mask fastening elements on the patient's head.