RU2108084C1 - Device for artificial pulmonary ventilation - Google Patents

Abstract

FIELD: medicine, medicinal equipment for first aid services, operational and revivificational departments of stationary establishments. SUBSTANCE: device has an air duct connected with a compressor blower of gaseous mixture flow connected with a control unit. Compressor blower is an axial spade compressor with reverse characteristics, a control unit has an input controller, central processor and an output controller. An input of input controller is connected with electric pressure transformers installed in an air duct, an output of central processor is connected with an input of output controller. The connection of compressor with a control unit is performed by connection of an output of output controller with compressor's power source. EFFECT: decreased volume-dimension characteristics of devices at simultaneous providing the possibility to realize different modes of VENTILATION. 4 dwg

Description

 The invention relates to the field of medical instrumentation. The primary field of use of the invention is the ambulance service, as well as the operating and resuscitation departments of hospitals.

 Known designs of mechanical ventilation devices are very diverse [1, 2].

 Typically, mechanical-driven mechanical ventilation devices are relatively complex and cumbersome electro-pneumatic-mechanical devices operated in operating rooms, intensive care units or ambulances. Such devices, for example, Engstrem, usually contain air lines for inspiration and expiration, a gas mixture flow generator, usually made in the form of a volume displacement chamber with an electro-mechano-gas-dynamic drive, means for setting and manual adjustment of the device's operation parameters, and also means for controlling some parameters of the artificial ventilation (pressure gauges in the exhalation lines, measured the flow rate of the gas mixture). Such devices have extremely unsatisfactory weight and size characteristics, which leads to significant inconvenience during their operation. In particular, when providing first aid, the patient can be connected to an apparatus installed in the car. Upon his arrival at the hospital, the problem arises of transporting resuscitation or operating room both to the patient himself and to the artificial lung ventilation apparatus that ensures his vital functions. Due to the considerable mass and dimensions of the apparatus, this, as a rule, turns out to be impossible and leads to a forced transition to ventilation manually.

 On the other hand, the portable lung ventilation apparatuses existing today do not provide a full range of respiratory therapy regimens that meets modern requirements [3, 4].

 Another significant drawback of the known devices is the complexity and complexity of disinfection of all air-related parts of the device associated with the patient, especially parts used in exhalation lines.

 A known apparatus to which these disadvantages are characteristic to a lesser extent (ed. St. USSR class 4 A 61 H 31/02, N 1209214). Improving the performance of this apparatus is achieved by using a gas mixture in the generator instead of the volume displacement chamber of two electric drive heaters, as well as by introducing electronic means of setting operation modes into the apparatus.

 The specified invention is closest to the proposed and selected for the prototype.

 The structural diagram of the apparatus that implements this invention includes two superchargers of the mixture with air ducts in the inspiration channel and the exhalation channel, as well as an electronically connected electronic control unit in the form of a shaper of time intervals and a matching relay block. The corresponding outputs of the latter are connected to the supply electrical inputs of both superchargers of the gas mixture.

 The operation of the prototype device is determined by the control unit, which, in accordance with the provisions of the regulators installed on it, generates control electrical signals that specify the time intervals of the respiratory cycles.

 The prototype device has a fairly acceptable weight and size characteristics. However, its use in a situation of transporting a patient on a stretcher without turning off or changing the ventilation mode is still difficult. The patient remains connected to the device with two air hoses that limit the possibility of operational work of medical personnel. In addition, the principles of creating a gas stream used in the prototype provide artificial ventilation of the lungs only in time-controlled mode with active (IPNPU). This excludes the possibility of implementing modern ventilation modes based on the use of volumetric and pressocyclic ventilation control methods. Therefore, the prototype device is practically very limited in application and can be used, at least according to the intention of its authors, only for performing mechanical ventilation in experimental animals in laboratory practice.

 The essence of the invention lies in the fact that in the known device for artificial ventilation of the lungs, containing an air duct, a supercharger of a gas mixture flow and a control unit for operating a supercharger, the supercharger is made in the form of an axial blade compressor with a reversible drive.

 The execution form of a particular patient, necessary to ensure the procedure of artificial ventilation, is not fundamental. Depending on the clinical situation, the connector may be represented by an endotracheal tube, facial or laryngeal mask.

 The proposed embodiment of the supercharger of the respiratory gas mixture allows to minimize its weight and size characteristics, bringing them to the extent that, when necessary, allow the supercharger and breathing mask to be combined into a single portable unit. Moreover, the connection of such a unit with the control unit of the apparatus acquires a purely electrical character and can be made in the form of a flexible cable line without imposing restrictions on its length. This makes it possible to carry out the entire apparatus in a portable version, which eliminates the previously noted drawback of the prototype device in the situation of its operation in an ambulance. The sterilization conditions of the apparatus elements are also facilitated.

 In the particular case, when it is necessary to perform artificial ventilation of the lungs using specially created breathing mixtures, the airway of the proposed device is equipped with a non-reversing valve, the inlet of which is connected to the source of the respiratory gas mixture, and the outlet to the atmosphere. With this form of execution of the duct through the valve can be connected to the generator of an artificial gas mixture, for example, as shown in figure 2.

 This solution provides the possibility of using the invention as a multifunctional diagnostic and treatment respiratory complex.

 In another particular case of the implementation of the invention, the air duct is made up of electric pressure and gas mixture flow transducers, and the control unit is made up of an input controller, a central processor with read-only memory, random access memory and an output controller, while the electrical outputs of the pressure and gas mixture flow transducers connected to the input of the input controller, the output of the input controller is connected to the input of random access memory, the output perativnogo storage device connected to the input of the CPU, the CPU output is connected to the controller input and the controller output is connected to a source of drive power of the compressor.

 This form of execution of the above-mentioned structural elements of the apparatus allows to obtain information about the state of the patient’s external respiration organs, in particular, about their biomechanical parameters and, using this information, implement adaptive control modes of the artificial lung ventilation process on the basis of specified programs.

 In FIG. 1 shows a structural diagram of an apparatus that implements the invention in its basic configuration; in FIG. 2 is a structural diagram of a multifunctional respiratory complex, implemented on the basis of the invention; in FIG. 3 is an example of a design of a supercharger of a gas mixture; in FIG. 4 is a block diagram of a control unit.

 Shown in figure 1 is a structural diagram of an apparatus that implements the invention in its basic configuration includes a breathing mask 1. The apparatus includes a supercharger 2 of the gas mixture flow, air duct 3, control unit 4 with an electric cable 5 connected via a connector 6 to the supercharger 2. In the particular case of implementation, a non-reversing valve 8 is connected through the connector 7 through the connector 7.

 An example of the use of the invention in the multifunctional respiratory complex is shown in figure 2. The complex includes an endotracheal tube 1 (equivalent to a breathing mask 1), a blower 2, an air duct 3 with a non-reversing valve 8 connected to it, a control unit 4, as well as a number of additional elements relative to the invention: a rotameter unit connected to the gas lines 10, 11 and 12, a manual ventilation unit 13 connected by air ducts 14 and 15 to the rotameter block 9 and the valve 8.

 As can be seen from FIG. 2, the proposed portable device can quite easily be included in a complex stationary medical diagnostic complex.

 In the example of the structural design of the gas mixture supercharger shown in Fig. 3, the supercharger 2 is combined with the air duct 3 into an integral part, which, taking into account the relatively small dimensions of the supercharger and the air duct, is the most preferred form of execution and eliminates the need for an interconnect detachable connection without creating the same time inconvenience when sterilizing the air channel.

 The aforementioned structural unit includes a housing 16, inside which a reversible electric motor 17 and guiding devices 18 and 19 are mounted and fixedly fixed. An impeller 21 is mounted on the shaft 20 of the electric motor 17, located between the guiding devices 18 and 19. The supercharger is connected to other elements of the respiratory circuit through pneumatic connectors 22 and 23, while in the embodiment of the supercharger shown in FIG. 3 (for the reasons indicated below), the connection with the breathing mask 1 is through the pneumatic the connector 22, and the connection with the generator (source) of the gas mixture through the pneumatic connector 23. In the housing 16 is also installed electrical converters (sensors) of pressure 24 and the flow rate of the gas mixture 25.

 The operation of the supercharger is as follows. When power is applied, the electric motor 17 starts to work. In this case, due to the rotational movement of the impeller 21 installed on its shaft 20, a gas mixture flows from the pneumatic connector 23 to the pneumatic connector 22. The operation of the engine 17 and the rotation of the impeller 21 continue until the end of the inspiration phase. At the end of the inspiration phase, the signal of the control unit 4 changes the direction of rotation of the electric motor 17 to the opposite, respectively, the direction of rotation of the impeller 21 changes, as a result of which the air (gas) flow is directed from the pneumatic connector 22 to the pneumatic connector 23. Air is sucked out from the main connected to the connector 22 (in the considered example, from the breathing mask) and its discharge into the trunk connected to connector 23. Thus, the exhalation phase is formed.

 The guide vanes 18 and 19, located on both sides of the impeller 21, help to optimize the angle of attack of the blades in the gas mixture stream.

 In the particular case of the proposed device, its duct is equipped with a non-reversing valve. It can be performed both as a part of a structural unit integrated with the air duct, and as a separate removable element connected to the air duct by means of a pneumatic connector. The latter embodiment is more preferable because it provides a wider variety of use cases of the invention. This is the case of implementation shown in figures 1 and 2.

 In another particular case of the invention, automatic control of the process of supplying the respiratory gas mixture is provided depending on the condition of the patient’s external respiration apparatus. In this embodiment, the apparatus in the duct 3 from the side of its connection with the source of the respiratory mixture installed electric transducers 24 pressure and 25 flow rate of the gas mixture (figure 3). The electrical outputs of these sensors through the cable connector 6 and the corresponding cable line are connected to the control unit 4 (figure 4).

 The control unit 4 includes a series-connected input controller 26, a central processor 27 comprising a read-only (eg, reprogrammed) memory 28 and connected to the random access memory 29, and an output controller 30 connected to the power supply 31.

 Analog electrical signals from sensors 24 and 25 are received at the input of input controller 26. Controller 26 converts these signals to digital form and, in accordance with the installed program, the driver enters them into random access memory 29. Central processor 27, in accordance with that stored in its permanent memory device 28, the main program for controlling artificial ventilation of the lungs sets the time cycle of the following cycles of inspiration, the duration of each phase in these cycles, the volume of air and in accordance with fixed in random access memory 29, the current values of the signals from the sensors 24 and 25 calculates the necessary adjustments ventilation parameters, adapting them to the external features of the patient breathing.

 The digital output signals of the central processor 27 are fed to the output controller 30, which in accordance with these signals regulates the supply of power from the power source 31 to the motor 17 of the supercharger 2. This provides the adaptive function of the patient’s external respiration to control artificial ventilation.

 The present invention provides the possibility of operating devices implemented on its basis in "field" conditions, i.e. in the absence of an electric network. At the same time, it allows, without stopping the process of artificial ventilation of the lungs, to supplement it with new elements that expand the therapeutic capabilities of the device. This turns out to be necessary, for example, during the transition from one stage of the medical-evacuation process to another.

Literature
1. Sykes MK, McNicol MN, Campbell EJM Respiratory sailure. Oxford 1969
2. Pierson DJ, Kacmarek RM Foundations of respiratory care. NJ 1992.

 3. Kassil V.L. Mechanical ventilation in intensive care. -M .: 1987.

 4. Report on the meeting of the IV Congress of Scientific Societies of Anesthesiologists and Resuscitators of the USSR. // Anesthesiology and resuscitation. 1990, N 4, p. 63, 77.

Claims (1)

 A device for artificial ventilation of the lungs, comprising an air duct connected to a compressor supercharger of the gas mixture flow and a control unit connected to it, characterized in that the compressor supercharger of the gas mixture flow is an axial vane compressor with the possibility of reverse, and the control unit contains an input controller, a central one a processor with ROM, RAM and an output controller, while the input of the input controller is connected to electric pressure and flow transducers installed in the duct gas mixture, the output of the input controller is connected to the input of the RAM, the output of the RAM is connected to the input of the central processor, the output of the central processor is connected to the input of the output controller, and the compressor is connected to the control unit by connecting the output of the output controller to the compressor drive power supply.

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