RU51340U1 - PORTABLE UNIT FOR INHALATION ANNESTICIAN - Google Patents

Abstract

In a portable device for inhalation anesthesia, on the one hand of which flowmeters and control handles are located, as well as a connector connected by a flexible pipe to the patient's breathing mask, and on the other hand, there are seats for removable portable cylinders, elements of shut-off and regulating pneumatic equipment are placed in the internal volume of the device made with the possibility of regulation, using the mentioned handles, the amount and percentage of gases supplied to the mask, and mounted on one side e multi-layer switching and mounting panel, in the middle part of which there are two flow meters, and inside there are channels for connecting elements of shut-off and control pneumatic equipment, cylinders and masks. As elements of shut-off and regulating pneumatic equipment, on the switching and mounting panel on one side of the flow meters, a manually operated pneumatic toggle switch is installed to turn on the compressed gas supply to the apparatus, a manually controlled mixer configured to control the ratio of the gas content in the mixture, and an air-operated direct-supply valve one of the gases in the mask, and on the other hand, a pneumatic button for turning on the valve for supplying one of the gases to the mask, a pressure and gas flow controller with manual control ION and pneumatically the two-stage control module and two pneumatically-follower amplifier. At the same time, the minimum dimensions and weight of the apparatus are ensured with an increase in vibration resistance and protection against vandalism due to the optimal arrangement of equipment in the housing, which excludes the use of non-rigid internal pipelines between the elements of pneumatic equipment, the functionality has been expanded for ventilation of the respiratory tract with respiratory gas and for monitoring and controlling the parameters of the mixture in the process of anesthesia, reconfiguration is provided to change the ratio of anesthetic and respiratory gas.

Description

The utility model relates to the field of medical technology and is intended for use in medical institutions, as well as in the field, as a universal anesthesia-respiratory apparatus for anesthesia, prevention of shock, therapy or restorative action using a gas mixture of oxygen or air and inert gas .

General anesthesia using inhalation components occupies a leading place in the structure of modern anesthesiology benefits. Anesthesia-respiratory apparatus means equipment for the dosed introduction of narcotic substances into the patient's body through the respiratory tract. The need to increase the mobility of equipment for anesthesia determines the interest of emergency doctors, institutions that deal with the consequences of emergencies, obstetric, military and military field medicine to equip portable anesthesia and respiratory equipment. When choosing narcotic gas, it is taken into account that, according to international standards, the production of such anesthetics as halothane, pentran, enflurane, isoflurane containing radicals of carbon, chlorine and fluorine should be suspended by 2030. The expediency of using, for example, xenon and / or helium determined by their physico-chemical properties - the ability to change the state of aggregation of phospholipids, as the main component of the cell membrane and synaptic link, and reversibly disrupt the transmission of nerve impulses, which allows It provides adequate, controlled anesthesia. Experimental and clinical studies confirm the presence of the indicated inert gases more pronounced analgesic properties (MAK - 50 ÷ 60%) than nitrous oxide (MAK - 105%). In addition, they are not toxic, devoid of side effects, do not cause carcinogenic, allergic and cardiodepressive effects, do not affect the composition and system of blood coagulation, immunity, environmentally friendly for

sick and surrounding staff. At the same time, the relatively high cost of inert gases makes it expedient to ensure the possibility of their regeneration.

Known portable device for inhalation anesthesia, connected to sources of anesthetic and respiratory gas, a housing, on one side of which there is a control panel with flow meters and inert gas and oxygen or air flow controllers, a mixer and a pressure relief valve. (one)

The disadvantages of this apparatus are low environmental safety and low efficiency due to the presence of chemical gas generators and leaks from the respiratory circuit, as well as the narrowness of functionality.

Also known is a portable device for inhalation anesthesia, connected to sources of anesthetic and respiratory gas, comprising a housing, a control panel with flow meters and inert gas and oxygen or air flow regulators, connectors configured to connect flexible pipelines for the patient’s breathing mask to remove used gas, replaceable cylinders, mixer and safety valve. (2)

The disadvantages of this device are the large dimensions and weight, which prevent carrying in the hands to the place of use, low impact and vibration resistance due to the large length of the internal pipelines and the shape of the body, causing stress concentration in the zone of sharp contact angles of the sides, limiting the possibility of transportation, narrow functionality , the lack of the possibility of preliminary and final ventilation of the respiratory tract with respiratory gas.

The technical task of the utility model is to create an effective portable device for inhalation anesthesia for work using inert gas, as well as expanding the arsenal of portable anesthesia and respiratory devices.

The technical result, which provides a solution to the problem, is that the minimum dimensions and weight of the apparatus are provided with a simultaneous increase in vibration resistance and

security against vandalism due to the optimal layout of the equipment in the housing, which excludes the use of non-rigid internal pipelines between the elements of pneumatic equipment and, therefore, the absence of intersections of internal pipelines, reliability is provided, because all elements of the pneumatic equipment are connected by the internal channels of the panel and thereby reduce the likelihood of leaks in their connections (compared with the piping connection), expanded the functionality for preliminary and final ventilation of the respiratory tract with respiratory gas and anesthesia with a mixture of the latter with inert gases, expanded functionality for monitoring and controlling the parameters of the anesthetic mixture during the anesthesia, quick and convenient reconfiguration is provided for Changes ratio anesthetic and breathing gas (oxygen or air).

The essence of the utility model is that in a portable device for inhalation anesthesia; on the one hand of which flow meters and control handles are located, as well as a connector connected by a flexible pipe to the patient’s breathing mask, and on the other hand, seats for removable portable cylinders are placed, elements of shut-off and regulating pneumatic equipment are arranged in the internal volume of the apparatus, made with the possibility of regulation, using the mentioned handles, the amount and percentage of gases supplied to the mask, and installed on one side of the multilayer patch panel, in the middle part of which there are two flow meters, and inside there are channels for connecting elements of shut-off and control pneumatic equipment, cylinders and masks.

It is preferable as elements of shut-off and control pneumatic equipment on the switching and mounting panel on one side of the flow meters to place a manual pneumatic toggle switch for turning on the compressed gas supply to the apparatus, a manually controlled mixer configured to control the ratio of the gas content in the mixture, and a pneumatically controlled valve

the direct supply of one of the gases into the mask, and on the other hand, the pneumatic button for turning on the valve for supplying one of the gases to the mask, a manually controlled gas pressure and gas flow controller, as well as a pneumatically controlled two-stage control module and two pneumatically controlled repeater-amplifiers, the trigger pneumatic toggle being connected to a channel for supplying one of the compressed gases, a pneumatic button, a pressure and flow controller, a valve for supplying one of the gases to the mask, a two-stage module and one of the repeater amplifiers, the second of which connected to the channel for supplying another gas, the mixer is connected to repeaters-amplifiers and flow meters, the valve for supplying one of the gases to the mask is connected to the pneumatic button and the mask, and the pressure and flow controller is connected to the pneumatic module associated with the pneumatic button, while the flow meters are made in the form of parallel mounted flowmeters with a transparent tube, a float and a vertical reading scale, or flow meters are made in the form of electric flow sensors with an autonomous power source, for example, with a battery Rhea.

In addition, one repeater amplifier, a flow meter, a pneumatic button for turning on the supply valve of one of the gases into the mask, and a valve for supplying one of the gases to the mask are configured to control and control the flow of oxygen or air, and the other repeater amplifier and flow meter are configured to control and control the flow of inert gas, for example, xenon or helium.

The drawing of Fig. 1 shows a block diagram of the pneumatic equipment of a portable apparatus for inhalation anesthesia, Fig. 2 is a schematic block diagram of the operation of a portable apparatus for inhalation anesthesia with balloons and a mask, Fig. 3 is a front view of a patch panel; Fig. 4 is a view A of FIG. 3, and FIG. 5 is a view B-B of FIG. 3.

On one side of the portable device for inhalation anesthesia, flowmeters are placed in the form of rotameters 1, 2 and control handles 3, 4, as well as a connector (fitting) connected by a flexible pipe 5 to the respiratory mask 6 of the patient. On the other hand, there are boarding

places for removable portable cylinders 7, 8, while in the internal volume of the apparatus there are elements of shut-off and regulating pneumatic equipment, made with the possibility of regulation, using the mentioned handles 3, 4, of the amount and percentage of gases supplied to the mask 6, and installed on one side of the multilayer patch panel 9, in the middle part of which rotameters 1, 2 are located, and channels (not marked) are made inside for connecting the elements of shut-off and control pneumatic equipment, cylinders 7, 8 and mask 6. Pa nel 9 is made of a “waffle” structure glued from several sheets in which slots are previously made for the formation of channels.

As elements of shut-off and regulating pneumatic equipment on the switching and mounting panel 9 on one side of the flowmeters 1, 2, a manual pneumatic trigger 10 is placed for switching on the supply of compressed gas to the apparatus, a mixer 11 with manual control of the handle 3, configured to control the ratio of gas contents in the mixture, and a pneumatically controlled valve 12 for direct supply of one of the gases to the mask 6. On the other hand from the flow meters 1, 2 there is a pneumatic button 13 for turning on the valve 12 for supplying one of the gases in m asku 6, a gas pressure and gas flow adjuster 14 with manual control of the handle 4, as well as a pneumatically controlled two-stage control module of two pneumatic converters 15, 16 and two pneumatically controlled repeater-amplifiers 17, 18.

The start pneumatic tumbler 10 is connected to a channel (not indicated) and a fitting 19 for supplying one of the compressed gases, a pneumatic button 13, a pressure and flow adjuster 14, a valve 12 for supplying one of the gases to the mask 6, a pneumatic converter 15 (from a two-stage pneumatic module) and a repeater-amplifier 17. The repeater amplifier 18 is connected to a channel (not indicated) and a fitting 20 for supplying another gas. The mixer 11 is connected to repeaters-amplifiers 17, 18 and to rotameters 1, 2, the valve 12 for supplying one of the gases to the mask 6 is connected to the pneumatic button 13 and to the mask 6, and the pressure and flow adjuster 14 is connected to the pneumatic converter 16 (from the two-stage pneumatic module ) associated with the pneumatic button 13.

Rotameters 1, 2 are made with a transparent tube, a float and a vertical reading scale (not indicated).

The flow meters can be made in the form of electric flow sensors with an autonomous power source, for example, with a battery (not shown).

Repeater-amplifier 17, flow meter (rotameter) 1, pneumatic button 13 for turning on the valve 12 for supplying one of the gases to the mask 6 and the valve 12 for supplying one of the gases to the mask 6 are configured to control and control the flow of oxygen or air, and the other repeater-amplifier 18 and a flow meter (rotameter) 2, configured to control and control the flow of inert gas, for example, xenon or helium. The cylinders 7, 8 have pressure reducers 21, 22 and pressure gauges 23, 24 at the outlet to ensure that gas is supplied to the apparatus with a constant pressure that remains unchanged as gas is taken from the cylinders 7, 8. The mixture is introduced into the mask 6 through the valve block 25, which can be integrated into the apparatus, to ensure the inhalation of the mixture from the apparatus and exhalation of the spent mixture into the atmosphere or into the xenon capture unit (not shown). In parallel with the mask 6, an elastic tight breathing bag 26 is connected to the output of the rotameters 1, 2.

The specific composition (execution) of the elements of the locking-regulating pneumatic equipment is preferably selected from commercially available logical pneumatic elements and may be different. In particular, the AMIE pneumatic toggle switch.306242004-02 and the AMIE pneumatic button can be used. 303659.006, repeater amplifier AMIE.426214.001-01, mixer AMIE.426215.027, module 426212.008, valve AMIE.306577.022, setpoint controller AMIE.336562.016, valve block AMIE.426213.015.

Portable anesthesia-respiratory apparatus operates as follows.

In a medical medical institution, the device is transferred to the desired room. In the absence of the possibility of transporting the patient to an inpatient medical facility, the doctor of the Ministry of Emergency Situations or an ambulance may perform the necessary or at least a preliminary procedure or surgery on the spot. The device is delivered by any type of transport and

easily transferred to the position providing anesthesia. The functioning of the apparatus is carried out according to the volume principle of a continuous flow with an active breath and consists in the formation and supply of a pre-prepared composition to the user of the respiratory medium. To supply gases to the connectors (fittings) 19, 20 of the device, portable cylinders 7, 8 fixed on the device and stationary, if available at the operation site, can be connected by flexible pipelines (hoses). Depending on the type of procedure and the presence of various gases at the venue, cylinders 7, 8 with breathing gas (oxygen or air), xenon, helium, another inert gas, and a mixture of breathing gas with one gas can be used in various combinations or with two inert gases in various proportions, or with nitrous oxide (N ₂ O). Below, the apparatus is described using oxygen (O ₂ ) and xenon (Xe) as an example for general anesthesia.

After sedation, induction of anesthesia, intubation, oxygen denitrogenation is performed. To do this, the pneumatic toggle switch 10 is switched to the position corresponding to the supply of oxygen from the cylinder 23, and the pneumatic button 13 is kept pressed. In this case, oxygen enters the mask 6 through the valve 12 bypassing the mixer 11 and rotameters 1, 2 from the cylinder 23 with oxygen for 3-5 minutes. After that, the pneumatic button 13 is released and through the repeater amplifiers 17, 18 oxygen and xenon are supplied from the cylinders 23, 24 to the mixer 11 with a flow rate and pressure determined by the position of the control handle associated with the setter 14, which controls the repeater amplifiers 17, 18 through the pneumatic converters 15, 16. The percentage of oxygen and xenon is determined by the position of the control handle associated with the mixer 11. According to rotameters 1, 2, the doctor visually monitors the parameters of oxygen and xenon entering the breathing bag 25. When patient fur coat bag 25 is emptied during exhalation - filled. If necessary, the control knobs 3, 4 can be quickly adjusted flow, pressure and the ratio of oxygen and xenon in the mixture. Upon reaching the surgical stage, a transition to the minimum flow of Xe: O _{2 is} carried out. At achievement of steady balance

xenon anesthesia in the ratio Xe: O ₂ (for example, 70:30), the xenon flow decreases and remains so until the end of the operation. At the end of anesthesia, xenon is washed out of the alveolar space of the lungs with oxygen or air for 4-5 minutes. For this, the pneumatic button 13 is again held pressed. In this case, oxygen enters the mask 6 bypassing the mixer 11 and rotameters 1.2 from the cylinder 23 with oxygen for 4-5 minutes.

The device allows to achieve high accuracy of measurement of parameters, does not require electricity, has a volume and weight that can be carried by people.

Thus, a portable anesthesia-respiratory apparatus was created, intended for anesthesia during surgical interventions of various profiles of any complexity and duration, meeting the safety requirements of the patient and medical staff, and the arsenal of portable anesthesia-respiratory apparatus was expanded.

At the same time, the minimum dimensions and weight of the apparatus are ensured with a simultaneous increase in vibration resistance and protection against vandalism due to the optimal layout of the equipment in the housing, which excludes the use of non-rigid internal pipelines between the elements of pneumatic equipment and, therefore, the absence of intersections of internal pipelines, reliability is provided, because all elements of the pneumatic equipment are connected by the internal channels of the panel, thereby reducing the likelihood of leaks in their connections, expanding the functionality for preliminary and final ventilation of the respiratory tract with respiratory gas and performing anesthesia with a mixture of inert gases, and expanding the functionality for monitoring and controlling the parameters of the anesthetic mixture in the process of anesthesia, quick and convenient reconfiguration is provided to change the ratio of anesthetic and respirator gas (oxygen or air).

Portable anesthesia-respiratory apparatus can be widely used due to its high strength and, therefore, transportability. Due to portability, light weight and high reliability, the device can be used in military hospitals in emergency working conditions and disaster medicine. Portable anesthesia and breathing apparatus can be effectively used in field surgery and obstetrics.

An economic analysis of the operation of the device in the mode of inhalation anesthesia showed a rather quick payback.

Information sources:

1. SU No. 1664330, 1991.

2. RU No. 17267, 2001 - (prototype).

Claims (6)

1. A portable device for inhalation anesthesia, on the one hand of which flow meters and control handles are located, as well as a connector connected by a flexible pipe to the patient’s breathing mask, and on the other hand, there are seats for removable portable cylinders, while the shutter elements are placed in the internal volume of the device -regulating pneumatic equipment, made with the possibility of regulation, using the mentioned handles, the amount and percentage of gases supplied to the mask, and installed on one multilayer side switching-circuit panel, in the middle of which are two of the flowmeter, and inside the channels made for connecting elements stop and regulating pneumatic equipment, tanks and masks. 2. The apparatus according to claim 1, characterized in that as elements of shut-off and regulating pneumatic equipment on the switching and mounting panel on one side of the flow meters, a manual pneumatic toggle switch is installed to turn on the supply of compressed gas to the device, a manually controlled mixer regulating the ratio of the gas content in the mixture, and a pneumatically controlled valve to directly supply one of the gases to the mask, and on the other hand, a pneumatic button to turn on the valve to supply one of the gases to the mask, Pressure and gas flow from the manual control, and two-stage pneumatically control unit and two pneumatically-follower amplifier. 3. The apparatus according to any one of claims 1 and 2, characterized in that the starting pneumatic tumbler is connected to the supply channel of one of the compressed gases, a pneumatic button, a pressure and flow adjuster, a valve for supplying one of the gases to the mask, a two-stage module and one of the repeater amplifiers , the second of which is connected to the channel for supplying another gas, the mixer is connected to repeaters-amplifiers and to flow meters, the valve for supplying one of the gases to the mask is connected to the pneumatic button and to the mask, and the pressure and flow controller is connected to the pneumatic module, connected mu with a pneumatic button. 4. The apparatus according to any one of paragraphs.1 and 2, characterized in that the flowmeters are made in the form of parallel mounted rotameters with a transparent tube, a float and a vertical reading scale. 5. The apparatus according to any one of claims 1 and 2, characterized in that the flow meters are made in the form of electric flow sensors with an autonomous power source, for example, with a battery. 6. The apparatus according to any one of claims 1 and 2, characterized in that one repeater amplifier, flow meter, pneumatic button for turning on the supply valve of one of the gases in the mask and the valve for supplying one of the gases to the mask are configured to control and control the flow of oxygen or air and another repeater amplifier and flow meter are configured to control and control the inert gas flow, for example, xenon or helium.