RU92333U1 - LUNG ARTIFICIAL VENTILATION DEVICE - Google Patents

Abstract

1. The apparatus of artificial ventilation, containing a valve box, a valve for turning on the supply of respiratory gas, a valve for the patient and a valve for restricting the working pressure, characterized in that the valve for turning on the supply of respiratory gas is located on the valve box. ! 2. The ventilator according to claim 1, characterized in that the valve for turning on the supply of respiratory gas is made in the form of a trigger.

Description

The utility model relates to medical breathing equipment, in particular, to artificial lung ventilation (IVL) devices operating at the frequency used to perform mechanical ventilation in emergency medical care, rescue services and hospitals.

Known manual breathing apparatus (1), containing a breathing bag, an exhaust valve, a patient valve and a mask. The patient valve incorporates a safety valve and a PDKV device. The ventilation frequency is set by the operator, and the tidal volume is determined by the amount of compression of the respiratory bag. The ratio of inspiratory and expiratory time is a low-regulated value.

When conducting mechanical ventilation, the operator spends quite a considerable effort on the compression of the bag and there is no clear fixation on the time of supply of respiratory gas by volume, inspiration time and the ratio of the phases of the respiration.

It is difficult to perform high-quality mechanical ventilation at higher frequencies (for example, in children).

The device has a fairly significant weight and dimensions.

The known mechanical ventilation device (2), created on the basis of standard pneumatic elements and performs the automatic ventilation function with fixed parameters of the respiratory rate, tidal volume and the ratio of the phases of the respiratory phase.

The device does not have adjustments to the respiration parameters, which significantly limits its range of application.

In addition, the apparatus has an unproductive gas flow rate for pneumatic element drive, large size and weight.

The purpose of this utility model is to simplify the design, increase usability, reduce the size and weight of the apparatus.

To achieve this goal, the breathing gas supply nozzle with the metering element is connected directly to the valve box, in which the patient valve and the working pressure limiting valve are located, and the metering supply enable valve is located between the metering element and the patient valve, while the metering breathing gas enable button is displayed on the outside of the valve box.

The essence of the utility model is illustrated by drawings (figure 1), which presents the design of the apparatus. The apparatus consists of a valve box I and a hose II, in which a fitting for supplying 1 respiratory gas with a metering element 2 is mounted.

Valve box I comprises a housing 3, in which a metering supply III enable valve, a patient IV valve, and a working pressure limiting valve V are located. Valve III is inserted into the housing 3 and secured by a fitting 1.

Valve III consists of a valve seat 4, valve 5, preloaded by a spring 6, and a button 7, which protrudes on the outer surface of the housing 3.

The patient’s valve IV is a non-reversible membrane valve containing a membrane 8 and an inspiratory valve 9. The membrane 8 is pressed against the body 3 by the patient fitting 10 and nut 11.

The valve limiting the working pressure V is placed on the same axis as the valve of the patient IV and contains a valve seat 12, valve 13, spring 14, which are closed by a cap 15 screwed onto the housing 3.

The operation of the device consists in periodically pressing the button 7.

When the button 7 is pressed, valve 5 opens and breathing gas is supplied to the valve of the patient IV, while the membrane 8 is pressed against the seat of the nozzle 10, excluding the outflow of respiratory gas into the atmosphere, and the inspiration valve 9 opens, allowing gas to pass into the patient's mask.

An act of inspiration occurs.

The on-time of valve 5 determines the amount of tidal volume supplied to the patient's lungs. The off-time of valve 5 determines the expiration time.

Exhalation occurs through a non-reversible valve IV due to the elasticity of the patient’s lungs, while the inspiratory valve 9 is closed, and the exhaled gas mixture lifts the membrane 8 and is discharged into the atmosphere.

The time between two successive starts of valve 5 determines the time of the respiratory cycle, and, consequently, the frequency of mechanical ventilation.

The ratio of the on time of the valve 5 and the time of its off state determines the ratio of the time of inspiration and expiration in the breathing cycle and is set by the operator.

The maximum working pressure on inspiration is limited by valve V, above which excess breathing gas is released into the atmosphere through valve 13 and the side openings in the cap 15.

The device has a low weight and dimensions and is placed on the mask of the patient. The force to turn on the valve 5 (the force on the button 7) does not exceed 15 kgf.

A clear fixation of the on-time of the supply valve, an operative change in the ventilation frequency and the ratio of the time of inhalation and exhalation in combination with small dimensions and weight ensure the convenience of using the device.

Claims (2)

1. The apparatus of artificial ventilation, containing a valve box, a valve for turning on the supply of respiratory gas, a valve for the patient and a valve for restricting the working pressure, characterized in that the valve for turning on the supply of respiratory gas is located on the valve box. 2. The ventilator according to claim 1, characterized in that the valve for turning on the supply of respiratory gas is made in the form of a trigger.