RU24384U1 - LUNG SIMULATOR - Google Patents

Description

To solve these problems, the proposed lung simulator, containing elastic fur with end surfaces, non-resistance and a vacuum gauge, is equipped with a tensile adjustment unit, implemented on pneumatic automation elements and including interconnected pneumatic pressure transducer with pressure indicator and actuator, with one end surface of elastic fur mechanically connected with the unit for adjusting lung extensibility, and the other has an input that is connected to a man-meter meter and an atmosphere of h Through adjustable non-resistance. In addition, the actuator is made in the form of a servomotor, the input of which is connected to a pressure adjuster, and the pressure indicator is calibrated in units of lung extensibility.

The drawing shows a functional diagram of the proposed lung simulator, where:

1- input simulator of the lungs;

2 - pneumatic resistance;

3- manovacuum meter;

4 - entrance elastic fur;

5- elastic fur;

6- unit for adjusting lung extensibility;

7- pneumatic pressure adjuster;

8- pressure indicator;

9- pneumatic actuator.

The lung simulator contains an input 1 of gas supply from mechanical ventilation apparatuses (IVL) to the simulator, pneumatic resistance 2 and manacase tlmeter 3, connected to the input 4 of the elastic fur 5, the end surface of which is mechanically connected to the lung stretch adjustment unit 6.

Unit 6 for adjusting the extensibility of the lungs contains a pneumatic pressure adjuster 7, the output of which is connected to the pressure indicator 8 and the input of the pneumatic actuator 9.

L01

when gas pressure is supplied from the pneumatic supply source (not shown in the drawing) to the lung extensibility adjustment unit 6, the pressure pneumosensor 7 at its outlet provides the set gas pressure in the controlled cavity of the actuating device 9. At the same time, the pressure of the gas entering the device 9 creates in the device 9 the force acting on the end surface of the elastic fur 5 and determines the extensibility of the fur 5 and the simulator as a whole, moreover, the pressure recorded by the indicator 8 and determining the force, we create The device 9 in this can be converted into tensile units with the corresponding graduation of indicator 8.

When breathing gas from any breathing apparatus enters the input 1 of the proposed lung simulator, this gas passes through a pneumatic resistance 2, the value of which is determined by its adjustment, and the manovacuum meter 3 shows the pressure in the fur 5 during the inhalation phase of the ventilator, i.e. in a lung simulator. This value can vary depending on the specified parameters of the artificial lungs - resistance to flow and the magnitude of lung extensibility.

Thus, the proposed technical solution using a pneumatic unit for adjusting lung extensibility allows, along with adjusting the flow resistance, to establish the lung extensibility in the simulator directly by the pointer device - indicator 8 and to free itself from springs that change their characteristics over time.

From the presented functional diagram of the proposed lung simulator and a description of its work, it can be 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.

 f 6 U3

The possibility of practical application and industrial development of the proposed simulator is not in doubt, because it differs in one thing from manufactured devices of a similar purpose used in healthcare and industry; it is manufactured in breathing apparatus.

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Claims (2)

1. A lung simulator containing elastic fur with end surfaces, a pneumatic resistance and a manovacuum meter, characterized in that it is equipped with a lung stretch adjustment unit, made on pneumatic automation elements and including a pressure adjuster with a pressure indicator and an actuator connected to each other, with one the end surface of the elastic fur is mechanically connected with the unit for adjusting the elongation of the lungs, and the other has an input that is connected to a manovacuum meter and the atmosphere through an adjustable th pnevmosoprotivlenie. 2. The lung simulator according to claim 1, characterized in that the actuator is made in the form of a pneumatic servomotor, the input of which is connected to a pressure adjuster, and the pressure indicator is calibrated in units of lung extensibility.