RU201819U1 - Universal gas dosing module - Google Patents

Abstract

The utility model relates to medical equipment and can be used to supply a respiratory mixture to a patient in the process of carrying out physiotherapeutic and therapeutic measures using breathing gas mixtures, oxygen or other medical gases. The technical result of the claimed utility model is the creation of a universal module for the dosed supply of gases, which can be used in inhalation equipment of various types, using both formed gas mixtures and individual gases as the working medium delivered to the patient, which has increased reliability and maintainability due to the modular design of the device ... The proposed universal gas dosing module can be used as part of inhalation equipment used in surgery - during general anesthesia and for pain relief, dentistry - for sedation of patients, neurology - for relief of pain syndromes and treatment of chronic pain, pulmonology - for the treatment of patients with respiratory insufficiency and other diseases of the bronchopulmonary system, combustiology - for the purpose of anesthesia in the treatment of burn surfaces, psychiatry - in the correction of neurotic conditions, in sports medicine, as well as in other preventive, therapeutic, rehabilitation measures that imply the supply of special gases and gas mixtures to the patient.

Description

The utility model relates to medical equipment and can be used to supply a respiratory mixture to a patient in the process of carrying out physiotherapeutic and therapeutic measures using breathing gas mixtures, oxygen or other medical gases. The universal gas dosing module can be used as part of inhalation equipment used in surgery - for general anesthesia and for pain relief from painful manipulations, dentistry - for sedation of patients, neurology - for relief of pain syndromes and treatment of chronic pain, pulmonology - for the treatment of patients with respiratory failure and other diseases of the bronchopulmonary system, combustiology - for the purpose of anesthesia in the treatment of burn surfaces, psychiatry - in the correction of neurotic conditions, in sports medicine, as well as in other preventive, therapeutic, rehabilitation measures that imply the supply of special gas mixtures to the patient.

The universal gas dosing module can be used as part of inhalation equipment used in medical, therapeutic and prophylactic and sanatorium-resort institutions, as well as in military field conditions, and in the transport of ambulance services and disaster medicine.

In the last decade, interest in the use of inert gases for medicinal purposes has grown significantly. Speaking about the advantages of inert gases as medical preparations, it should be noted that they are not only devoid of toxic, teratogenic, mutagenic, carcinogenic, allergenic and embryotoxic effects, but they are also environmentally friendly and safe products that do not pose a threat to either the patient or medical personnel. ...

Helium-oxygen gas mixtures have been used in medical practice since 193 October for the treatment of patients with respiratory failure, due to the unique physical properties of this inert gas - low density and viscosity, which allow creating a laminar flow of the gas mixture in the patient's airways, thereby reducing the load on respiratory center. It is known to use an oxygen-helium mixture to prevent the development of decompression sickness [Hyldegaard O, Madsen J. Effect of hypobaric air, oxygen, heliox (50:50), or heliox (80:20) breathing on air bubbles in adipose tissue. J Appl Physiol Bethesda Md 1985.2007 Sep; 103 (3): 757-62.], Treatment of patients with airway obstruction [Smith SW, Biros M. Relief of imminent respiratory failure from upper airway obstruction by use of helium-oxygen: a case series and brief review. Acad Emerg Med. 1999; 6 (9): p. 953-956.], In the complex therapy of pneumonia [Krasnovsky AL, Grigoriev SP, Zolkina IV, Alekhin AI. Inhalation of heated oxygen-helium mixture in the complex treatment of patients with community-acquired pneumonia. Russian medical journal. 2013; (1): p. 10-14], correction of the conditions of patients in the postoperative period [Yahagi N, Kumon K, Haruna M, Watanabe Y, Matsui J. Helium / oxygen breathing improves hypoxemia after cardiac surgery. Artif Organs .; 21 (1): p. 24-27] and others.

Xenon has been used in medicine as a means for inhalation anesthesia and pain relief in Russia since 1999. For more than 20 years of clinical experience, hundreds of scientific papers have been published, including a number of guidelines for the use of xenon in the treatment of pain syndromes [The use of medical xenon in the treatment of acute and chronic pain syndromes: guidelines / Kryukov E.V. and others - M .: FGKU "GVKG im. Academician N.N. Burdenko "Ministry of Defense of the Russian Federation, 2015. - 36 p.], Borderline mental disorders [The use of medical xenon in the treatment of stress-related neurotic mental disorders: guidelines / Bubeev Yu.A. and others - M .: FGBU UNMTS UDP RF, 2014, - 36 p.], withdrawal conditions in narcology [The use of medical xenon in the treatment of opium withdrawal syndrome: guidelines / Utkin S.I. et al. - M .: Research Center of Narcology, 2014. - 32 p.], for premedication in dentistry [The use of medical xenon in combined anesthesia and sedation in outpatient dental practice: guidelines / Shugailov I.A. and others - M .: GBOU VPO MGMSU MH RF, 2015. - 40 p.], as well as during general anesthesia during surgical interventions [Combined xenon anesthesia in children: guidelines / Bagaev V.G. et al. - M .: NII NDKhiT, 2015. - 34 p.].

In these areas, a number of Russian and international patents are known that describe methods of using inert gases in the treatment of various diseases: RF Patent No. 2524765 on the use of xenon for the prevention and treatment of neurotic stress-induced disorders, RF patent No. 2695350 on the treatment of pain syndromes. In addition, exploratory research on the use of other inert gases in medicine is underway. For example, FR 2960779 proposes the use of krypton and krypton containing mixtures for the treatment of renal and hepatic failure, and FR 2964036 proposes the use of kryptonoxenone mixtures for the protection of cerebral vessels.

All this testifies to the extreme importance of the task of developing modern inhalation equipment for the delivery of inert gases and respiratory mixtures based on them to patients.

A device for treating stress [RF patent 2524765] is known from the prior art, containing gas sources, a gas supply control device, a closed breathing circuit for inhalation with a gas mixture, including a breathing mask, a gas mixing unit connected to a gas supply control device, containing an additional a gas mixing unit connected to a gas supply control device, as well as a switching device for said gas mixing units connected to a breathing mask and interconnected with each gas mixing unit with the possibility of forming two closed breathing circuits during inhalation. The first closed breathing circuit is designed for inhalation with helium-oxygen mixture. The second closed breathing circuit is designed for inhalations with helium-xenon-oxygen mixture before the onset of signs of gas exposure at the second stage of inhalation.

A significant drawback of this device is the presence of two gas mixing units and two closed breathing circuits, which leads to a complication of the device design and, as a consequence, the operating conditions. In addition, such a device cannot be unified for the use of various inert gases, since requires the creation of special mixing blocks for each new gas.

There is a known method of forming a respiratory gas mixture and an apparatus for its implementation [RF patent 2072241]. The proposed apparatus includes a device for producing a gas mixture with a source of compressed gas connected by pipelines through regulators of the composition and flow of the gas mixture, a breathing bag, an inhalation and exhalation valve with a mask, an oxygen gas analyzer and a control unit. The device for producing a gas mixture is made in the form of containers with compressed oxygen and at least one of the following gases: helium and / or argon and / or neon and / or krypton and / or xenon and / or radon, and / or nitrogen, and / or nitrous oxide, and / or sulfur hexafluoride, or a mixture thereof, connected to the breathing bag by means of pipelines with stop valves. The container with compressed oxygen is equipped with a valve regulated by a control unit, and the apparatus is equipped with a circulation circuit formed by connected pipelines, a breathing bag, a flow rate booster, a temperature regulator and at least one absorber of carbon dioxide, moisture and harmful micro-impurities. The circulation circuit is connected to an oxygen gas analyzer and is additionally equipped with a carbon dioxide gas analyzer and a temperature meter, which together with the oxygen analyzer form a measuring unit electrically connected to the control unit. The mask is connected to the circulation circuit by means of pipelines with valves.

Such a device is multifunctional and has a certain degree of versatility. To obtain a breathing mixture in this solution, containers with compressed gases are used, from which, through a reduction system and valves controlled by a control unit, gases are supplied to the breathing bag, where they are mixed. However, in such a scheme, due to the absence of a flow meter, there is no possibility of controlling the gas flow rate, thus the composition of the resulting gas mixture in the breathing bag remains unclear. The presence of only an oxygen sensor in the breathing circuit does not allow monitoring the content of the second gas or gas mixture, since nitrogen is always present in the breathing gas mixture, which is removed from the patient's lungs and tissues.

The closest in essence and the achieved result is a gas dosing unit, RF patent 182740, located in one housing, inside which a pneumatic unit is installed on the front side, to which a gas flow regulator, a breathing mixture pressure sensor, and a flow meter are attached. Inside the body there are a computer and a control controller connected to each other by a high-frequency wired interface, and the control controller is connected with the ability to collect information from a second gas pressure sensor, a breathing gas pressure sensor, an oxygen pressure sensor, a gas concentration sensor and a flow meter and supply control commands to the solenoid valves, flow regulator and external electromechanical valve; a cooling fan is installed inside the back of the case, and outside there is a power input for connecting the gas metering unit power supply button, HDMI output for connecting a monitor, an output for connecting an uninterruptible power supply, an output for connecting a monitor power supply and an output for connecting a card reader; on the front side of the body there is an outlet for connecting an electromechanical valve, an outlet for connecting a gas concentration sensor.

The specified unit has the ability to work with two gases, oxygen and the second - an inert gas. In addition, the device has the ability to analyze the content of oxygen and a second inert gas - xenon, krypton, or argon. The proposed gas metering unit has low maintainability due to the location of all the unit's elements in one housing.

The purpose of the present utility model is to create a universal device for metering gas supply, integrated into the inhalation equipment. The device has a modular design and provides the ability to work with individual gases.

The technical result of this utility model is:

creation of a universal module for the dosed supply of gases, which can be used in inhalation equipment of various types, using separate gases as the working medium delivered to the patient;

increasing the reliability and maintainability of inhalation equipment due to the modular design of the device;

increasing the reliability of the equipment due to the use of filters for mechanical impurities located at the inlet of the gases supplied to the Device.

To achieve a technical result, this utility model uses:

1. A universal gas dosing module containing a pneumatic unit configured to connect a connected computer and a control controller, characterized in that the pneumatic unit is made in the form of two pneumatic modules, each of which is a gas line containing a series-connected mechanical filter gas impurities, an inlet gas pressure sensor, a shut-off solenoid valve, a flow meter, a precision pressure reducer, a precision gas pressure sensor is installed at the outlet of the pneumatic unit, and the elements of the pneumatic unit are configured to receive control commands from a control controller containing a power supply input, an input for power control, an output for connecting a monitor, an output for connecting a battery and an output for connecting an information carrier and having the ability to collect information and send control commands.

2. A universal gas dosing module according to claim 1, characterized in that the elements of the pneumatic module are located on the pneumatic plate.

The essence of the utility model is illustrated by the following examples.

Example 1.

The universal gas dosing module contains a pneumatic unit containing two pneumatic modules, adapted to connect a computer and a control controller connected to each other.

The control controller contains an input for power supply, an input for power management, an output for connecting a monitor, an output for connecting batteries, an output for connecting an information carrier, inputs for collecting information from the elements of a pneumatic module - a gas pressure sensor (2) at the input to a pneumatic module, a flow meter (4) , as well as a precision pressure sensor (6) of the gas mixture at the outlet from the pneumatic module to the breathing circuit, and the possibility of supplying control commands to the elements of the pneumatic module, a shut-off solenoid valve (3), a precision pressure reducer (5).

Each pneumatic module is made in the form of a gas line containing a filter of mechanical impurities of gas (1), a gas pressure sensor at the inlet to the pneumatic module (2), a shut-off solenoid valve (3), a flow meter (4), a precision pressure reducer (5) ... A precision pressure sensor (6) of the gas mixture is located behind the pneumatic modules at the outlet from the pneumatic unit to the breathing circuit, FIG. one.

A breathing apparatus using a gas dosing module can operate in either an open or a closed breathing circuit. To ensure the operation of the breathing circuit of the apparatus, in the closed circuit mode, oxygen and second gas concentration sensors (7) and an external electromechanical valve (8) are additionally connected to the controller of the universal gas dosing module, Fig. one.

When using clean gases, usually oxygen and a second gas, as a working medium, the universal gas dosing module works as follows.

The universal gas dosing module can be controlled via special data entry systems, for example, via a touch screen. As a rule, the user of the inhalation technique sets the required parameters of the respiratory mixture, inhalation time and starts the command to start inhalation. The commands, in accordance with the inhalation program, are sent by the computer to the controller, which controls the elements of the pneumatic modules, while the program adjusts the parameters of the gas supply based on the readings of the oxygen and second gas sensors (7), the gas mixture pressure sensor and flow meters of the pneumatic modules (4).

When the command “start inhalation” is sent to the control computer, the controller opens the shut-off solenoid valve (2) of either the first or the second pneumatic module, depending on the concentration of gases in the breathing circuit. In this case, the corresponding gas from the pressure vessel, through the reduction system up to 4 ... 6 atm, is supplied to the input to the corresponding pneumatic module, passes through the filter of mechanical impurities of gas, and the shut-off solenoid valve (3), the flow meter (4), which records the amount of gas consumed, and is fed to a precision pressure reducer (5), which maintains a predetermined, close to atmospheric pressure in the breathing circuit. When the precision pressure sensor of the gas mixture (6) registers overpressure, the controller issues a command to open the external electromechanical valve (8) to release the overpressure of gases into the atmosphere.

When the oxygen concentration in the breathing circuit drops below a preset value, usually 19%, which is detected by the oxygen pressure sensor (7), the controller issues a command to the shut-off valve (2) of the pneumatic module used to supply oxygen.

Example 2.

It differs from example 1 in that three pneumatic modules are used in the universal gas metering module, and a third gas control module is added to the concentration sensor (7). This supplies oxygen and two other gases to the breathing circuit.

Example 3.

It differs from examples 1 and 2 in that the pneumatic modules of the universal gas metering module are made on a pneumatic plate.

The universal gas dosing module can be controlled via special data entry systems, for example, via a touch screen. As a rule, the user of the inhalation technique sets the required parameters of the respiratory mixture, inhalation time and starts the command to start inhalation. The commands, in accordance with the inhalation program, are sent by the computer to the controller, which controls the elements of the pneumatic modules, while the program adjusts the parameters of the gas supply based on the readings of the oxygen and second gas sensors (7), the gas mixture pressure sensor and flow meters of the pneumatic modules (4).

When the command "start inhalation" is sent to the control computer, the controller opens the shut-off solenoid valve (2) of either the first or the second pneumatic module, depending on the concentration of gases in the breathing circuit. In this case, the corresponding gas from the pressure vessel, through the reduction system up to 4 ... 6 atm, is supplied to the input to the corresponding pneumatic module, passes through the filter of mechanical impurities of gas, and the shut-off solenoid valve (3), the flow meter (4), which records the amount of gas consumed, and is fed to a precision pressure reducer (5), which maintains a predetermined, close to atmospheric pressure in the breathing circuit. When the precision pressure sensor of the gas mixture (6) registers overpressure, the controller issues a command to open the external electromechanical valve (8) to release the overpressure of gases into the atmosphere.

When the oxygen concentration in the breathing circuit drops below a preset value, usually 19%, which is detected by the oxygen pressure sensor (7), the controller issues a command to the shut-off valve (2) of the pneumatic module used to supply oxygen.

Example 3.

It differs from example 2 in that three pneumatic modules are used in the universal gas metering module, and a third gas control module is added to the concentration sensor (7). This supplies oxygen and two other gases to the breathing circuit.

Example 4.

It differs from examples 1, 2 and 3 in that the pneumatic modules of the universal gas metering module are made on a pneumatic plate.

Claims (2)

1. A universal gas dosing module containing a pneumatic unit made with the possibility of connecting a computer and a control controller connected to each other, characterized in that the pneumatic unit is made in the form of two pneumatic modules, each of which is a gas line containing a filter of mechanical impurities connected in series gas pressure sensor, inlet gas pressure sensor, shut-off solenoid valve, flow meter, precision pressure reducer, a precision gas pressure sensor is installed at the output of the pneumatic unit, and the elements of the pneumatic unit are configured to receive control commands from a control controller containing a power supply input, a control input for power control, an output for connecting a monitor, an output for connecting a battery and an output for connecting an information carrier, and having the ability to collect information and send control commands. 2. A universal gas dosing module according to claim 1, characterized in that the elements of the pneumatic module are located on the pneumatic plate.

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