RU24385U1 - LUNG MODEL - Google Patents

Description

LUNG MODEL

The proposed technical solution relates to the field of medical technology, in particular, to lung simulators and can be used to study the mechanics of respiration during respiratory therapy in various medical institutions and medical practice, as well as to control the respiration parameters of respiratory equipment.

Known lung simulators, for example, the mechanical model of the lungs MML-3, pulled out by the domestic industry (AOOT Krasnogvardeets, St. Petersburg). Also known is a lung simulator LS-800, manufactured in Germany.

Common to the known devices and the proposed technical solution is the presence of elastic fur, pneumatic resistance and manovacuum meters in them.

General, they have the disadvantages of known devices:

the impossibility of independently adjusting the magnitude of the extensibility of each lung using a dial gauge with a digitized scale;

the need to select spring mechanisms when using lung simulators to calibrate respiratory equipment for various age groups of patients;

- large weight and size characteristics of the known devices due to the use of lever-spring mechanisms in their design.

The main objectives of the proposed technical solution is to eliminate these drawbacks and, in particular, to provide independent adjustment of the extensibility of each lung directly by the corresponding vacuum gauges, graduated in units of extensibility of the lungs, as well as improving the accuracy of maintaining the established parameters of the lung model and reducing the weight and size characteristics of the model.

To solve these problems, the proposed lung model, containing two elastic bellows with end surfaces, a pneumatic resistance and a manovacuum meter is equipped with two non-vacuum rarefaction sensors, two rarefaction indicators and two actuators, each of which is placed inside the elastic fur and mechanically connected to the end surfaces of the elastic fur, the inputs of both elastic bellows are connected to the common input of the lung model through adjustable pneumatic resistance and connected to the corresponding mana uummetrami, and inputs the two actuating devices associated with respective setters vacuum and are connected to respective vacuum indicators. In addition, actuators are made in the form of elastic means connected by their inputs to rarefaction indicators, and rarefaction indicators are graded in units of lung extensibility. The drawing shows a functional diagram of the proposed lung model, where:

1 - gas supply inlet;

2, 3 - adjustable pneumatic resistance;

4, 5 - vacuum manometers;

6, 7 - inputs of elastic bellows;

8, 9 - elastic furs;

10, 11 - actuators;

12,13 - inputs of actuators;

14, 15 - rarefaction pneumosensors;

16, 17 - rarefaction indicators.

The lung model contains a gas supply inlet 1, for example, from the outlet of various breathing apparatuses, adjustable pneumatic resistances 2, 3, manovacuometers 4, 5, connected with the corresponding inputs 6 and 7 of the elastic bellows 8 and 9. Between the end surfaces of the bellows 8 and 9 are located connected with them actuators 10 and 11, inputs 12 and 13

which are connected to the corresponding) rarefaction air sensors 14 and 15 and rarefaction indicators 16 and 17.

The lung model works as follows.

When gas pressure is supplied from a pneumatic supply source (not shown in the drawing) to rarefaction switches 14 and 15 at their outputs and associated actuators 10 and 11, a vacuum is provided, the value of which is individually set by switches 14 and 15. Moreover, the vacuum in the devices 10 and 11 creates a force acting on the end surface of the elastic bellows 8 and 9 and determines the extensibility of bellows 8 and 9 when respiratory gas 6 and 7 are supplied to their inlets, and the rarefaction values recorded by indicators 16 17 and determining the forces generated by the devices 10 and 11 in this case determine the amount of extensibility in each lung model and can be converted to the corresponding units with extensibility grading indicators 16 and 17.

When the respiratory gas from any breathing apparatus is inlet 1 of the proposed lung model, this gas passes through adjustable pneumatic resistances 2 and 3, the magnitude of which is determined by their adjustment, and the vacuum manometers 4 and 5 show the pressure values in bellows 8 and 9, i.e. in each of the patient’s artificial lungs during the inspiratory phase of the breathing apparatus. These values can vary depending on the set parameters of each artificial lung — resistance to gas flow and lung extensibility.

Thus, the proposed technical solution allows, along with independent adjustments to the resistance to the flow of each artificial lung, to individually set the lung elongation in the model directly by the arrow devices 16 and 17 and to free itself from spring mechanisms that change their characteristics over time.

From the presented functional diagram of the proposed lung model and a description of its operation, it is seen that the proposed technical solution ensures the achievement of the tasks and the claimed technical effect.

The claimed technical solution, according to the author, is not obvious, and its technical effect is quite high.

The possibility of practical application and industrial development of the proposed lung model is not in doubt, because it compares favorably with manufactured devices of a similar purpose used in healthcare and the medical industry; it is manufactured; it has breathing equipment.

Claims (2)

1. A lung model containing two elastic bellows with end surfaces, pneumatic resistance and a manovacuum meter, characterized in that it is equipped with two rarefaction pneumatic sensors, two rarefaction indicators and two actuators, each of which is placed inside the elastic fur and mechanically connected with the end surfaces of the elastic fur , while the waters of both elastic bellows are connected to the common input of the lung model through adjustable pneumatic resistances and are connected to the corresponding manovacuometers, and in the strokes of both actuators are connected with the corresponding vacuum reducers and connected to the corresponding vacuum indicators. 2. The lung model according to claim 1, characterized in that the actuators are made in the form of elastic means connected by their inputs to the rarefaction indicators, and the rarefaction indicators are graded in units of lung extensibility.