SU1284550A1 - Method of artificial ventilation of the lungs - Google Patents

Abstract

The invention is intended for carrying out artificial respiration and makes it possible to increase the efficiency of the feed gas consumption, mainly with an increase in the upper limit of minute ventilation, and to simplify the design. The device contains a mode switch 1, a master unit 2, a 3 minute ventilation controller, gerators 4 and 5, a separation unit 6 with fur 11, check valves 7, 8, 12 and 13j relief valve 9, controlled exhalation valve 14, mask 15 and a gas supply source 16. Switch 1 at the command of unit 2 alternately switches to inspiratory mode, in which gas comes from source 16, to controller 3, and to exhalation mode, when no gas supply occurs. When you inhale the gas enters the injector. 5, into the lower cavity of the valve 9 ,. in node 6 and on to the patient. With large ventilators, the oxygen-air mixture enters unit 6 and through injector 4. In exhalation mode, the flow of gas into the injectors is stopped, the control chamber of valve 9 is emptied. The gas from the node 6 is released into the atmosphere, the fur 11 expands, providing a new portion of the gas intake, which allows to expand the limits of the minute ventilation adjustment while reducing the specific consumption of feed gas. 2 Il. (Lu y shh 4 JV g /

Description

The invention relates to medicine and can be used for artificial respiration.

The purpose of the invention is to increase the efficiency of gas feed consumption, mainly with an increase in the upper limit of the minute ventilation, and at the same time simplifying the design.

FIG. 1 is a schematic diagram of the pulmonary ventilation apparatus; in fig. 2 - minute ventilation controller.

The device for artificial ventilation of the lungs contains a switch of 1 modes, controlled by a driver unit 2. The output of the switch is connected to the controller of 3 minutes ventilation. The regulator has two outputs, one of which is connected with an injector 4, and the other with an injector 5. A check valve 7 is placed between the injector 4 and a separating unit 6, and a check valve 8 and the diaphragm valve are placed between the injector 5 and unit 6 9 reset. The control chamber 10 of the valve 9 is connected to the injector 5 and the valve 8, the discharge chamber to the node 6 and the atmosphere. ,

In unit 6 there is a respiratory fur 11, which forms, with check valves 12 and 13, controlled valve 14 of the mask and mask 15, a breathing circuit. The device is powered from the source

16 gas supply.

The minute ventilation regulator of the lungs has an inlet channel 17 and outlet channels 18 and 19. Between the inlet; and output channels are located needle valves 20 and 21, pressed to the seats by springs. The control member 22 is associated with a screw that, when rotating, first opens valve 21, and then, after it is fully opened and in contact with valve 20 of the stem of valve 21, valve 20.

The device works as follows.

The mode switch 1 is activated by the command of the driver unit 2 alternately in the inspiration mode, in which gas from the gas supply source 16 is supplied to the 3-minute ventilation controller, and in the exhaust mode, in which the gas supply stops. Gas entering the inlet as al

17 the regulator, through the valve 2G and the output channel 19 is directed to the injector 5, then to the lower cavity

valve 9 and through the non-return valve 8 into the separation unit 6. At the same time, the membrane 10, under gas pressure, closes the outlet to the atmosphere from the discharge chambers and the entire oxygen-air mixture leaving the injector 5 enters the node 6. The fur 11 located Node 6 is compressed, and the gas mixture contained in it enters the respiratory tract of the patient through the breathing circuit, and an artificial inhalation occurs. As the handle 22 is further rotated, the shank of the valve 21 presses the valve 20, opens it and the gas begins to flow into the node 6 through the outlet channel 18, the injector 4 and the check valve 7.

Thus, at low ventilators, the oxygen-air mixture enters the separation unit 6 from one injector, and at large vents, simultaneously from two injectors. When the switch is set to exhalation mode, the flow of gas into the injectors is stopped, the control chamber 10 of the valve 9 is emptied. The diaphragm valve 9 is lowered, providing gas from the node 6 to the atmosphere. Fur 11 expands, taking a new portion of gas through valve 12. The patient exhales through the exhalation valve 14 into the atmosphere or into the hose attached to the valve 14.

The device allows one to expand the limits of adjustment of minute ventilation, while reducing the specific flow rate of feed gas, since the use of injectors in a narrow range of flow variation makes it possible to increase their injection rate and make them more resistant to anti-. to the grip.

Claims (1)

Formula of inventions A ventilator containing a controlled mode switch, an inspiratory injector, a minute ventilation regulator with a valve and control, a separating unit, relief and discharge valves with control chambers, connecting hoses and elements differing in that , with the aim of increasing the efficiency of gas supply consumption, mainly with an increase in the upper limit minute ventilation, and at the same time simplifying the design, it is equipped with additional injectors between the mode switch and the separation unit and the regulator valve mechanically connected with its control body, the control chambers, the discharge chambers are connected to the separating unit by means of check valves, and the control chambers of the valves of the valve are connected directly to the separating unit.