SU152547A1 - - Google Patents

Description

The known artificial respirators do not provide the possibility of artificial respiration during anesthesia using closed and semi-closed systems.

This disadvantage is eliminated in the proposed apparatus for artificial respiration. A distinctive feature of the apparatus is the location of the inhalation and exhalation furs in a closed circuit so that they are activated by the pressure and vacuum generated in the casing. The design of the apparatus allows artificial respiration in open, closed, half-open and semi-closed systems.

The drawing shows a diagram of the apparatus for artificial respiration.

The main part of the apparatus is the inhalation and expiration fur 1 and 2, located concentrically under the bell 3 of transparent material. The bell has a movable stop 4, which is secured in the selected position by a nut 5. On the stop there is an arrow 6, indicating the fixed volume on the scale. A switch 7 is connected to the space under the bell by means of levers 7 and a spring 8. The diaphragm 10 of the mechanism abruptly changes from one position to another when a certain pressure or vacuum is established under the bell 3. The pressures and dilutions caused by the transition of the membrane 10 from one position to another are determined by the tension of the spring 8. With the membrane 10, the spools // and 12 are connected.

The pressure and vacuum under the bell are created when the blower 13 is operated. The valve 14 allows to simultaneously change the speed of reaching the pressure and vacuum under the bell, and the valve 15 allows at the same time to change the speed of setting under the bell of the vacuum.

No. 152547 2 -

The inhalation fur 1, depending on the position of the spool, // is connected either to the nozzle 16 leading to the atmosphere, or to the tee 17 of the patient via the humidifier-heater 18. The 2 exhalation fur is likewise connected to either the nozzle / I leading to the atmosphere, or to the tee 17 through the meter 20 volumes. A 17 gauge gauge connected to the tee 17 is also connected to the tee 17.

The device works as follows.

The fur / and 2 is driven by pressure (downward movement) or vacuum (upward movement) created in the sealed space under the transparent bell 3 by attaching this space to the blowing or suction side of the blower 13. At the same time, this space is communicated with the switching mechanism 9, providing a strictly fixed position of the spools 11 and 12 of the switchgear. Two fixed positions of the dispenser are possible: the inhalation position and the expiratory position. In the inhalation position, the space under the bell is communicated with the suction side of the blower, the pressure connection of the blower is in communication with the atmosphere. In this case, the membrane of the switching mechanism is bent outwards. The vacuum created under the diaphragm tries to draw it inward, but the spring 5 prevents it from being thrown through the dead position only at a certain amount of vacuum. In the inhalation position, the picture is reversed; the suction nozzle of the blower is in communication with the atmosphere, forcing - with the space under the bell 5. The membrane 10 of the switching mechanism is drawn inward. A movable stop 4 is fixed in the bell cover, which limits the movement of bellows and, consequently, the volume of breathing. The position of the stop is pre-set manually, after which it must be fixed with a nut 5. The movement of the fur during work is carried out from the stop to the bottom of the bellows, when they are compressed (inhale), and from the lower position up to the stop (exhalation). Switching occurs at the moment of one of the extreme positions of the bellows, when the pressure or vacuum required for switching is established in the space under the bell.

The lungs of the patient are communicating with the viexoM / inhalation during inhalation using the spool 11 and during exhalation with the exhalation fur 2. During inhalation, when downward movement of the bellows, the gas from the inhalation breath 1 enters the patient’s lungs, and the gas from the fur 2 exhales out through the i / 5 nozzle into the atmosphere or into the anesthesia apparatus (when operating in a closed system). After the prescribed volume has been supplied and the bellows are fully compressed, switching occurs, the expiratory act begins. In this case, the lungs communicated with the fur 2 exhalation. Fur / breath communicated with the atmosphere or with an anesthetic apparatus. Since a certain part of the volume of exhaled gas is discharged directly into the atmosphere or 3 anesthesia apparatus and does not get into the exhalation mechanism, the volume meter 20 is a kind of control valve on the exhalation line. With a fully relaxed spring, the exhalation spring will suck gas through this valve, maintaining a pressure close to atmospheric in the lungs, more precisely in the lungs, some separation equal to the valve resistance will be maintained. With a small path to compressing the spring, we will receive the greater the vacuum in the lungs, the greater will be the resistance of the valve.

In order to control the pressure and break-up in the apparatus, a man-vacuum meter with a button is provided, which is connected to a special tap on the patient's tee. In order to regulate the minute fan, the chi -: and, consequently, the respiration rate of the discharge and suction line of the blower (compressor 13) are interconnected by means of a valve 14. With the valve completely closed, all the air supplied by the compressor will flow into the space under the bell, which will correspond to the maximum ventilation. When the valve is fully open (provided that the resistance of the flow area is sufficiently low) all the air supplied by the blower 13 will circulate through the faucet, and nothing will flow into the apparatus, i.e. the minute of ventilation will be zero. All intermediate positions of the crane will ensure the regulation of minute ventilation from the minimum to the maximum value. In order to set the required value of the ratio of inspiratory time to expiratory time on the suction line, exhaust to the atmosphere is provided by means of a valve 15.

When using the apparatus without anesthesia, the patient’s lungs will be air moistened and heated in the humidifier-heater 18, and there is a possibility to enrich it with oxygen if the latter is supplied to the pipes 16. When the pipes for exhalation and inhalation of the anesthesia device are connected to pipes 16 and 19 , the device will supply the patient with an anesthetic mixture formed in the bag of the anesthetic device. When the gases are supplied through the anesthesia instrument dosimeter, the anesthesia system will be closed or semi-closed in any vaporized or gaseous anesthesia. If the nozzle 16 is connected with the anesthesia apparatus and the gas mixture exhaled by the patient is discharged through the nozzle 19, then the anesthesia system is half open. If to connect any vaporizer of narcosis of narcosis to the pipe 16, then the system of anesthesia will be carried out.

The device provides active inhalation and active exhalation during artificial respiration through any system of anesthesia and without it. The magnitude of the dilution can be adjusted from 5 cm of water to 0 at the request of the physician.

Subject invention

Apparatus for artificial respiration, containing a blower, a spool-type distributor and a pipeline system with valves and a humidifier, characterized in that, in order to ensure the possibility of carrying out artificial respiration during anesthesia on closed, open, half-closed and half-open systems during active inhalation and exhalation and when switching from inspiration to expiration and back upon reaching a given volume, the inspiratory fur and expiratory fur are located in a closed housing, in which pressure or vacuum is created.

- 3 - № 152547