RU108973U1 - ARTIFICIAL LUNG VENTILATION DEVICE - Google Patents

Abstract

 1. An artificial lung ventilation apparatus comprising a pneumatically coupled constant flow generator, an inhalation line with flow, pressure sensors and a safety valve for aspirating air, an exhalation line with a controlled exhalation valve and a flow sensor, a patient tee connected to inhalation and exhalation lines, characterized in that the device additionally contains an oxygen concentration sensor and a first non-return valve installed in series at the output of the constant flow generator, a second non-return valve, anovlenny inlet controllable exhalation valve, moreover, is further installed a pressure source unit and the oxygen supply unit, wherein the pressure source module output pneumatically connected through the choke valve air supply unit with an oxygen generator and the input of the constant flow. ! 2. The apparatus according to claim 1, characterized in that the oxygen supply unit is made in the form of a pneumatically coupled adjustable throttle, a pressure regulator and a first proportional solenoid valve, the input of the first proportional solenoid valve being connected to the output of the pressure regulator. ! 3. The apparatus according to claim 1, characterized in that the pressure source module for the controlled exhalation valve is made in the form of a pneumatically coupled diaphragm pump, a second proportional solenoid valve and a pneumatic distributor, the output of the diaphragm pump being pneumatically connected to the input of the second proportional electromagnetic valve and through the pneumatic distributor the control cavity of the controlled exhalation valve, and the output of the air distributor

Description

The utility model relates to medical equipment, namely, devices for artificial lung ventilation (IVL) and will find application in the intensive care and intensive care units of clinical hospitals and medical research institutes.

The closest analogue in the set of essential features to the claimed utility model is an apparatus for artificial ventilation of the lungs "PHASE" according to patent RU 62016 U1, publ. 03/27/2007, comprising a patient tee, an electric motor with a speed sensor, a blower, a flow sensor, a safety valve and an exhalation valve with a PEEP regulator, a flow sensor and a pressure meter in the patient line, an electric motor control module, a ventilator control module, and a patient tee connected to one output through a safety valve with a pressure gauge in the patient line, and another outlet with an exhalation valve with a PEEP regulator, in addition, the engine speed sensor is connected to the motor control module.

The disadvantages of the known closest analogue are:

- the inability to implement modern modes of ventilation support with controlled pressure,

- lack of funds for conducting ventilation with a prescribed mixture of respiratory mixture,

- the lack of the ability to provide ventilation modes manually, including using oxygen supply,

- large overall mass characteristics,

- significant noise during operation,

- low functional and operational qualities.

The task to which the claimed utility model is directed is to increase patient safety, expand the functional and operational capabilities of the product.

The technical result is to ensure patient safety while improving the quality of ventilation support modes.

The problem is solved, and the technical result is achieved by the fact that in an artificial lung ventilation apparatus containing a pneumatically coupled constant flow generator, an inspiratory line with flow sensors, pressure and a safety valve for aspirating atmospheric air, an exhalation line with a controlled exhalation valve and a flow sensor, a patient tee, associated with the lines of inhalation and exhalation, additionally installed:

- an oxygen concentration sensor and a first check valve installed in series at the output of the constant flow generator,

- a second check valve installed at the inlet to the controlled exhalation valve,

- pressure source module,

- oxygen supply unit,

- the output of the pressure source module is pneumatically connected through an atmospheric air intake valve to the oxygen supply unit and the input of the constant flow generator,

- the oxygen supply unit is made in the form of a pneumatically coupled adjustable throttle, a pressure regulator and a first proportional solenoid valve, wherein the input of the first proportional solenoid valve is connected to the output of the pressure regulator,

- the pressure source module for the controlled exhalation valve is made in the form of pneumatically connected diaphragm pump, the second proportional solenoid valve and pneumatic distributor, moreover, the output of the diaphragm pump is pneumatically connected to the inlet of the second proportional electromagnetic valve and, through the pneumatic distributor, with the control cavity of the controlled exhalation valve and the output the pneumatic distributor is pneumatically connected to the inlet of the atmospheric air intake valve.

A causal relationship between the totality of essential features and the technical result achieved is that:

- placement at the output of the constant flow generator of the oxygen concentration sensor allows you to control the oxygen concentration in the constant flow of the respiratory mixture supplied by the generator,

- placement at the output of the constant flow generator of the first non-return valve, at the entrance to the controlled exhalation valve of the second non-return valve and the installation of the pressure source module allows you to switch the gas flows on the inhale and exhale of the patient in controlled ventilation modes,

- installation of the oxygen supply unit and its implementation in the form of a pneumatically coupled adjustable throttle, a pressure regulator and a first proportional electromagnetic valve, as well as a pneumatic connection of the input of the first proportional electromagnetic valve with the output of the pressure regulator, allow the formation of an oxygen-air mixture supplied to the patient by the operator ,

- the implementation of the pressure source module for a controlled exhalation valve in the form of a diaphragm pump, a second proportional electromagnetic valve and a pneumatic distributor, as well as a connection of the output of the diaphragm pump to the input of a second proportional electromagnetic valve and, through a pneumatic distributor, with a control cavity of the exhalation valve, allow you to adjust the pressure in this cavities, providing reliable switching of gas flows in the acts of inhalation and exhalation, as well as work in ventilation modes with controlled pressure or with positive specific pressure of the end of expiration (PDKV).

- pneumatic connection of the output of the pressure source module through the atmospheric air suction valve with the oxygen supply unit and the input of the constant flow generator allows you to implement the ventilation mode "manually", including the possibility of supplying an oxygen-air mixture of a given composition.

The essence of the claimed technical solution is illustrated by a graphic image, which shows a schematic pneumatic diagram of the apparatus.

The ventilator (Fig. 1) contains a constant flow generator 1 based on an adjustable blower, a first check valve 2, an inhalation line 3, a flow sensor 4, a pressure sensor 5, an exhalation line 6, a controlled exhalation safety valve 7, a flow rate sensor 8, a tee 9 patient, oxygen concentration sensor 10, second non-return valve 11, oxygen supply unit 12, pressure regulator 13, first proportional solenoid valve 14, atmospheric air inlet valve 15, suction relief valve 16, control pressure source module 17 I for the controlled safety valve 7 of the exhalation line, the diaphragm pump 18, the second proportional solenoid valve 19, the air distributor 20, the adjustable throttle 21 (valve).

The device operates as follows.

The main element of the apparatus is the generator 1 (Fig. 1) of the air flow (controlled blower), which supplies a gas stream of a given size and composition to the breathing circuit.

In accordance with the ventilation parameters set by the operator, for example, tidal volume, ventilation frequency and relative inspiratory time, the program of the apparatus calculates the rotation parameters of the blower motor to ensure the required volumetric gas flow rate at the output of generator 1 and the minute ventilation is independent of the pressure in the respiratory circuit .

After pressing the start button (conditionally not shown in Fig. 1) and attaching the tee 9 to the patient’s airways, the diaphragm pump 18 and the second proportional valve 19 are turned on by a signal from the program in the pressure source module 17. In this case, air from the pump 18 exit through an open channel the pneumatic distributor 20 enters the control cavity of the exhalation valve 7, increasing the pressure in it, the level of which limits the maximum pressure in the patient’s lungs and is determined by the position (degree of opening) of the second proportional valve 19, ravlyaetsya program. Under the influence of this pressure, the membrane of the controlled safety valve 7 expiration hermetically closes the line 6 of the exhalation of the patient and the respiratory mixture through the sensor 4 flow through line 3 of the inspiration enters the lungs of the patient. An act of inspiration occurs.

The constituent parts of the inhaled gas, air from the atmosphere and oxygen, enter the suction line of the generator 1 from the oxygen supply unit 12. In this case, oxygen enters the block 12 through the pressure regulator 13 and the first proportional valve 14. The program calculates the oxygen supply from the given concentration and provides it by controlling the proportional valve 14: when the set oxygen supply is less than the specified minute ventilation, the generator 15 s through valve 15 the necessary flow rate sucks in air from the atmosphere. The oxygen concentration in the respiratory mixture supplied by the generator 1 is monitored by a sensor 10 on the inspiration line.

At the end of the inspiratory time, an act of passive exhalation of the patient begins. The gas supply to line 3 of the inspiration stops. At this point, the program includes a pneumatic distributor 20. In this case, the control cavity of the expiratory membrane valve 7 communicates with the atmosphere through the distributor 20, under the influence of pressure in the patient's lungs, the valve 7 opens and gas from the lungs, through the tee 9, the expiration line 6, the flow sensor 8 and the return valve 11 enters the atmosphere. The volume of gas exhaled by the patient is determined by the program according to the signals of the flow sensor 8.

The expiration time is determined by the relative inspiratory time specified by the physician (the ratio of inspiratory time to the time of the respiratory cycle). The magnitude of this ratio, the program generates a signal to turn on the gas supply from the generator 1 flow and the beginning of the next breath. The breathing cycle repeats.

In the modes of auxiliary ventilation, the device produces an act of inspiration at the time of the patient's appearance of an independent attempt to inspire, determined by the program by a signal from the sensor 4 flow. Moreover, in all modes of auxiliary ventilation is carried out:

a) switching to inspiration - “downstream”, i.e. due to the appearance of a predetermined flow rate of the inhaled gas in the waiting interval in the tee 9 of the patient;

b) in the interval of waiting for an attempt to supply the line 3 of the inhalation of the set reference gas flow established by the operator to create a small positive pressure in the patient's tee 9. To recognize the attempt, the program compares the sensitivity set by the operator in the form of a flow rate with the speed created by the patient’s attempt in the flow sensor 4;

c) in the absence of a patient’s inhalation - automatic switching to exhalation after the expiration of the waiting interval set by the operator.

The pressure in the respiratory circuit of the device is measured by a pressure sensor 5, the signal of which is processed by the program to indicate the pressure and the alarm when it falls below an acceptable level. In addition, for operation in controlled-pressure ventilation or with PEEP, the program uses the signal from the pressure sensor 5 to control the inclusion of the second proportional valve 19 and the air distributor 20 when the lungs reach the specified levels of inspiratory pressure or end of exhalation.

The safety valve 16 limits the pressure in the inspiratory line to 100 cm of water. Art.

In spontaneous breathing mode, the flow generator 1 is turned off, and the patient inhales the gas mixture through the atmospheric air intake valve 15 and exhales through the flow sensor 8 and the exhalation valve 7.

During inspiration, the generator 1 delivers a predetermined tidal volume into the patient's lungs. The non-return valve 2, installed on the inspiration line (inspiration valve), ensures during the expiration act the passage of all gas exhaled by the patient through the flow sensor 8, according to the signals of which the program calculates the value of the exhaled volume.

For manual ventilation (when the generator 1 is turned off), an elastic self-expanding bag (not shown conventionally) is connected to the inlet fitting of the suction valve 16. Air during compression of the bag enters through the generator 1 through the inspiration line into the patient's lungs and, simultaneously, through the air distributor 20 into the control cavity exhalation valve 7, closing it. An act of inspiration occurs. When the bag is straightened, it is filled with air, a pressure drop in the control cavity of the exhalation valve 7 and its opening (act of exhalation). Manual ventilation can be carried out with oxygen enriched air. For this, the outlet fitting of the adjustable choke 21 (valve) is connected by a tube to a special fitting of the self-expanding bag, and, opening the choke 21, the necessary oxygen supply to the bag is established.

Thus, the proposed technical solution allows to increase patient safety in case of emergency by providing manual ventilation, for example, using a self-expanding bag, including using oxygen supply, as well as improving the quality of ventilation support modes.

Claims (3)

1. An artificial lung ventilation apparatus comprising a pneumatically coupled constant flow generator, an inhalation line with flow, pressure sensors and a safety valve for aspirating air, an exhalation line with a controlled exhalation valve and a flow sensor, a patient tee connected to inhalation and exhalation lines, characterized in that the device additionally contains an oxygen concentration sensor and a first non-return valve installed in series at the output of the constant flow generator, a second non-return valve, anovlenny inlet controllable exhalation valve, moreover, is further installed a pressure source unit and the oxygen supply unit, wherein the pressure source module output pneumatically connected through the choke valve air supply unit with an oxygen generator and the input of the constant flow. 2. The apparatus according to claim 1, characterized in that the oxygen supply unit is made in the form of a pneumatically coupled adjustable throttle, a pressure regulator and a first proportional solenoid valve, the input of the first proportional solenoid valve being connected to the output of the pressure regulator. 3. The apparatus according to claim 1, characterized in that the pressure source module for the controlled exhalation valve is made in the form of a pneumatically coupled diaphragm pump, a second proportional solenoid valve and a pneumatic distributor, the output of the diaphragm pump being pneumatically connected to the input of the second proportional electromagnetic valve and through the pneumatic distributor the control cavity of the controlled exhalation valve, and the output of the pneumatic distributor is pneumatically connected to the inlet of the atmospheric air intake valve.