CN219440303U - Intelligent artificial upper respiratory tract device - Google Patents

Abstract

The utility model belongs to the technical field of medical appliances, and particularly discloses an intelligent artificial upper respiratory tract device which comprises an atomization humidifier main body, a respiratory pipeline main body, a power supply electric control host machine and a power supply electric control cable, wherein the respiratory pipeline main body comprises a double-cavity respiratory pipeline, a threaded pipe joint and a switching elbow, a semiconductor condensation plate is arranged in the double-cavity respiratory pipeline, the semiconductor condensation plate divides the interior of the double-cavity respiratory pipeline into an air inlet cavity and an air return cavity, and a liquid storage tank is arranged on the side edge of the double-cavity respiratory pipeline; an integrated wire harness plug and an artificial airway joint are arranged on the side edge of the atomizing humidifier main body; the atomizing humidifier main body is internally provided with a medicine storage tank, and the medicine storage tank is provided with an ultrasonic atomizing sheet, a medicine adding port and an air outlet; the ultrasonic atomization sheet is opposite to the artificial airway joint, so that liquid medicine mist can be reduced to contact objects to form water drops, the mist entering the lung is increased, effective atomization humidification is achieved, the pressed-in gas is heated by the semiconductor condensation plate, and the expired gas is condensed.

Description

Intelligent artificial upper respiratory tract device

Technical Field

The utility model relates to the technical field of medical equipment, in particular to an intelligent artificial upper respiratory tract device.

Background

Keeping the airway clear is the basic life support, and endotracheal intubation and tracheotomy are the primary means of artificial airway establishment. Mechanical ventilation of trachea cannula is an important measure in general anesthesia of operation and is also a main measure for the management of hospital emergency, ward and ICU airway; tracheotomy is also a primary open modality for artificial airways for patients requiring long-term ventilator therapy or emergency airway patients. In the rescue of the severe patients with the new coronary pneumonia in recent years, the establishment of the artificial airway breathing machine treatment greatly improves the treatment success rate, and fully illustrates the important position of the artificial airway in the treatment of the severe patients.

Some patients with established artificial airway ventilation do not have spontaneous breathing, require machine assisted breathing, and some have spontaneous breathing. However, such patients have in common: the upper respiratory tract completely loses the functions of heating, humidifying and filtering the inhaled gas.

The atomization treatment is widely applied to clinic as a very good treatment administration mode, and is mainly applied to patients with spontaneous breathing by using the prior technical equipment and means, and the patients can inhale atomized liquid medicine particles or powder into the lung by themselves to achieve the treatment effect. While for patients requiring ventilator support we consider that such patients are bedridden for a longer period of time, nebulized therapy is more desirable than patients with spontaneous breathing. The artificial airway of the patient is supported by invasive respiration, and the air flow impacts the liquid medicine atomization mode to enable a large amount of air flow to enter the airtight respiratory pipeline to influence respiratory parameters of the patient, even cause lung injury, which is obviously not preferable.

In the mechanical ventilation process of the patient with the artificial airway, gas directly enters the main airway without being humidified and heated by the normal upper airway, and besides taking away the body temperature of the patient, moisture in the airway mucosa is excessively lost, so that dry scabs and phlegm blocks are formed in the airway to cause pulmonary infection.

In order to solve the problems of atomization treatment of a patient with an established artificial airway and humidification and heating of inhaled gas, the utility model provides an intelligent artificial upper respiratory tract device which integrates atomization treatment, gas humidification, gas heating and gas flow measurement. The method has the advantages of effective atomization treatment, quantitative time-sharing humidification of the airway, heating of the inhaled air, cooling of the exhaled air, reduction of the entering of the exhaled vapor into the respirator, and quantitative measurement of the inhaled air, and is particularly significant for artificial airway patients with spontaneous breathing.

Disclosure of Invention

The present utility model is directed to an intelligent artificial upper airway device that solves the above-mentioned problems set forth in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the intelligent artificial upper respiratory tract device comprises an atomization humidifier main body, a respiratory pipeline main body, a power supply electric control host and a power supply electric control cable, wherein the respiratory pipeline main body comprises a double-cavity respiratory pipeline, a threaded pipe joint and a switching elbow, the threaded pipe joint and the switching elbow are respectively positioned at two ends of the double-cavity respiratory pipeline, a semiconductor condensation plate is arranged in the double-cavity respiratory pipeline and divides the interior of the double-cavity respiratory pipeline into an air inlet cavity and an air return cavity, a liquid storage tank is arranged on the side edge of the double-cavity respiratory pipeline, and the switching elbow is connected to an inlet of the atomization humidifier main body; an integrated wire harness plug and an artificial airway joint are arranged on the side edge of the atomizing humidifier main body, and the power supply electric control host is connected to the integrated wire harness plug through a power supply electric control cable; the medicine storage tank is arranged in the atomizing humidifier main body, an ultrasonic atomizing sheet, a medicine adding port and an air outlet are arranged on the medicine storage tank, and the ultrasonic atomizing sheet is opposite to the artificial airway joint; the ultrasonic atomization piece just can reduce liquid medicine mist contact object to form the water droplet to artifical air flue joint, increase the water smoke that gets into in the lung, reach effective atomizing humidification, provide the power for this device through the electric host computer, the screwed pipe joint is used for connecting the play return circuit pipeline of breathing machine, the breathing machine end of giving vent to anger can be with gas indentation patient's lung in, the semiconductor condensation plate heats the gas of impressing, and condense the gas of exhaling, the ultrasonic atomization piece adopts the little hole atomizing piece (presume atomizing orifice according to medical gas humidification guide) to atomize humidification, and the ultrasonic atomization piece is opened only when inhaling the gaseous phase, reduce the liquid medicine extravagant, and, can not produce wet lung.

Preferably, the inner side of the threaded pipe joint is provided with an air inlet end and an air outlet end, the air inlet end is communicated with the air inlet cavity, the air outlet end is communicated with the air return cavity, and the air inlet end and the air outlet end are respectively connected with an air outlet and an air return opening of the breathing machine.

Preferably, the refrigerating surface and the heating surface of the semiconductor condensing plate are respectively positioned in the air return cavity and the air inlet cavity, the air pressed in by the breathing machine enters the air inlet cavity, the heating surface of the semiconductor condensing plate is used for heating the air, and the expired air enters the air return cavity for condensation treatment.

Preferably, the liquid storage tank is located on the air return cavity, the liquid storage tank is detachably fixed on the double-cavity breathing pipeline, the semiconductor condensation plate can be provided with a liquid drainage groove, condensed water can be drained into the liquid storage tank below, when the air flowing back enters the air return cavity, water vapor in the air of the refrigeration surface of the semiconductor condensation plate can be collected through the liquid storage tank, and when the liquid storage tank is full of water, the liquid storage tank can be detached for emptying.

Preferably, the medicine storage tank is fixed in the atomizing humidifier main body through the connecting frame, and the medicine adding port and the air outlet of the medicine storage tank are both arranged on the outer side of the atomizing humidifier main body, and the air outlet is provided with a semipermeable membrane, so that air can be removed through the semipermeable membrane, and liquid can not be removed, so that the medicine liquid can be conveniently injected.

Preferably, a gas flow sensor is arranged in the gas inlet cavity, the gas flow sensor is electrically connected with the ultrasonic atomization sheet, when the sucked gas flow reaches a set value, the ultrasonic atomization sheet is triggered to start, and when the gas flow is smaller than the set value, the ultrasonic atomization sheet is closed.

Preferably, the power supply electric control host is provided with a host data display screen and a host function switch, and is electrically connected with the gas flow sensor, the semiconductor condensing plate and the ultrasonic atomization sheet respectively, and the power supply electric control host can adopt a PLC program.

Compared with the prior art, the utility model has the beneficial effects that: the utility model is connected with the outlet loop pipeline of the breathing machine through the threaded pipe joint, gas can be pressed into the lung of a patient through the outlet end of the breathing machine, the semiconductor condensing plate heats the pressed gas and condenses the reflowed gas, and the condensed vapor can be collected through the liquid storage tank, so that the vapor in the gas exhaled by the patient is effectively removed, the vapor in the threaded pipe joint is reduced, and bacterial proliferation and breathing machine damage are reduced.

Through when impressing gaseous, ultrasonic nebulizer starts and produces fog and get into patient's lung along with the air current, ultrasonic nebulizer closes during expiration, reduces that atomized liquid gets into the breathing circuit and causes the liquid medicine extravagant and the breathing machine damages to satisfy patient's atomizing treatment that the breathing machine supported, positive effect of air flue in the aspect of reducing the patient's lung complication of breathing machine treatment.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic diagram of the power supply electric control host structure of the present utility model;

FIG. 3 is a schematic view of the internal structure of the breathing circuit body of the present utility model;

FIG. 4 is a schematic view of the internal structure of the atomizing humidifier according to the present utility model;

FIG. 5 is a schematic diagram showing the internal structure of the atomizing humidifier according to the present utility model.

In the figure: 1. an atomizing humidifier body; 101. an artificial airway joint; 102. an integrated harness plug; 2. a breathing circuit body; 201. a dual lumen respiratory tube; 2011. an air inlet cavity; 2012. an air return cavity; 202. a threaded pipe joint; 2021. an air inlet end; 2022. an air outlet end; 203. a switching elbow; 3. a power supply electric control host; 301. a host data display screen; 302. a host function switch; 4. a power supply electric control cable; 5. a liquid storage tank; 6. a semiconductor condensing plate; 7. a gas flow sensor; 8. a drug storage tank; 801. a medicine adding port; 802. an exhaust port; 803. ultrasonic atomizing sheet.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In the description of the present utility model, it should be noted that the azimuth or positional relationship indicated by the terms "vertical", "upper", "lower", "horizontal", etc. are based on the azimuth or positional relationship shown in the drawings, and are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or element referred to must have a specific azimuth, be constructed and operated in a specific azimuth, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

Referring to fig. 1-5, the present utility model provides a technical solution: the intelligent artificial upper respiratory tract device comprises an atomization humidifier main body 1, a respiratory pipeline main body 2, a power supply electric control host 3 and a power supply electric control cable 4, wherein the respiratory pipeline main body 2 comprises a double-cavity respiratory pipeline 201, a threaded pipe joint 202 and a switching elbow 203, the threaded pipe joint 202 and the switching elbow 203 are respectively positioned at two ends of the double-cavity respiratory pipeline 201, a semiconductor condensation plate 6 is arranged in the double-cavity respiratory pipeline 201, the semiconductor condensation plate 6 divides the interior of the double-cavity respiratory pipeline 201 into an air inlet cavity 2011 and an air return cavity 2012, a liquid storage tank 5 is arranged at the side edge of the double-cavity respiratory pipeline 201, and the switching elbow 203 is connected to an inlet of the atomization humidifier main body 1; an integrated wire harness plug 102 and an artificial airway joint 101 are arranged on the side edge of the atomizing humidifier main body 1, and a power supply electric control host 3 is connected to the integrated wire harness plug 102 through a power supply electric control cable 4; the medicine storage tank 8 is arranged in the atomizing humidifier main body 1, an ultrasonic atomizing sheet 803, a medicine adding port 801 and an exhaust port 802 are arranged on the medicine storage tank 8, and the ultrasonic atomizing sheet 803 is opposite to the artificial airway joint 101; the ultrasonic atomization piece 803 just can reduce liquid medicine mist contact object to form the water droplet to artificial airway joint 101, increase the water mist that gets into in the lung, reach effective atomizing humidification, provide the power for this device through the automatically controlled host computer of power 3, screwed pipe joint 202 is used for connecting the play return circuit pipeline of breathing machine, breathing machine end 2022 can be with gas indentation patient's lung in, the gas of semiconductor condensation board 6 will impress heats, and condense the gas of exhaling, the ultrasonic atomization piece 803 adopts the little hole atomizing piece (set for atomizing orifice according to medical gas humidification guide) to atomize humidification, and the ultrasonic atomization piece 803 is opened only when breathing in, reduce the liquid medicine extravagant, and, can not produce wet lung.

Further, an air inlet end 2021 and an air outlet end 2022 are disposed inside the threaded pipe joint 202, the air inlet end 2021 is communicated with the air inlet cavity 2011, the air outlet end 2022 is communicated with the air return cavity 2012, and the air inlet end 2021 and the air outlet end 2022 are respectively connected with an air outlet and an air return opening of the breathing machine.

Further, the cooling surface and the heating surface of the semiconductor condensation plate 6 are respectively located in the air return cavity 2012 and the air intake cavity 2011, the air pressed in by the breathing machine enters the air intake cavity 2011, the air is heated by the heating surface of the semiconductor condensation plate 6, and the exhaled air enters the air return cavity 2012 for condensation treatment.

Further, the liquid storage tank 5 is located on the air return cavity 2012, the liquid storage tank 5 is detachably fixed on the dual-cavity breathing pipeline 201, the semiconductor condensation plate 6 is provided with a liquid drainage groove, condensed water can be drained into the liquid storage tank 5 below, when the air flowing back enters the air return cavity 2012, water vapor in the air of the refrigerating surface of the semiconductor condensation plate 6 can be collected through the liquid storage tank 5, and when the liquid storage tank 5 is full of water, the condensed water vapor can be detached and emptied.

Further, the medicine storage tank 8 is fixed in the atomizing humidifier main body 1 through the connecting frame, and the medicine adding port 801 and the air exhaust port 802 of the medicine storage tank 8 are both arranged on the outer side of the atomizing humidifier main body 1, and the air exhaust port 802 is provided with a semipermeable membrane, so that air can be exhausted through the semipermeable membrane, and liquid can not be exhausted, so that the medicine liquid can be conveniently injected.

Further, a gas flow sensor 7 is disposed in the gas inlet cavity 2011, the gas flow sensor 7 is electrically connected with the ultrasonic atomization sheet 803, when the inhaled gas flow reaches a set value, the ultrasonic atomization sheet 803 is triggered to start, and when the gas flow is smaller than the set value, the ultrasonic atomization sheet 803 is closed.

Further, the power supply electric control host 3 is provided with a host data display screen 301 and a host function switch 302, and the power supply electric control host 3 is electrically connected with the gas flow sensor 7, the semiconductor condensation plate 6 and the ultrasonic atomization sheet 803 respectively, and the power supply electric control host 3 can adopt a PLC program.

Working principle: during the use, the artificial airway connects 101 and patient's air flue to be connected, connect the return circuit pipeline of breathing machine through screwed pipe joint 202, the air is pressed into the air inlet cavity 2011 of two-chamber breathing pipeline 201 through the breathing machine, make the gas get into patient's lung through switching elbow 203 and atomizing humidifier main part 1, in-process, when gas through gas flow sensor 7, flow sensor begins measuring gas flow, semiconductor condensate plate 6 starts simultaneously, make the radiating surface of semiconductor condensate plate 6 produce heat, utilize the heat that semiconductor condensate plate 6 produced to heat gas, make patient's inhaled gas be close human body temperature, simultaneously, when the inhaled gas flow reaches the setting value of gas flow sensor 7, gas flow sensor 7 can be with information transfer to the automatically controlled host computer of power 3, utilize automatically controlled host computer of power 3 to trigger the supersound atomizing piece 803 start, make supersound atomizing piece 803 produce fog and get into patient's lung along with the gas that has the temperature, when gas flow is less than the setting value of gas flow sensor 7, supersound piece 803 is closed, so can accomplish effective atomizing, and reduce the humidification medicine or the liquid medicine that has taken the humidification medicine to have got into patient's lung and has heated the process and accomplished the lung after having accomplished the humidification.

When the breathing machine lets the patient breathe out gas according to setting, the air outlet valve of breathing machine can be closed, the air return valve can be opened, the gas in the patient's lung can be discharged owing to atmospheric pressure and the effect of breathing muscle crowd, atomizing device is closed this moment, when the gas that patient's lung exhaled gets into the return air chamber 2012, the condensation effect of the cooling surface of semiconductor condensation board 6 makes the vapor condensation in the exhaled gas into water, then the water just that becomes can flow into liquid storage pot 5, can reduce the steam content in the exhaled gas like this, avoid bacterium hyperplasia in the screwed pipe joint 202, avoid the breathing machine damage. The mechanical ventilation of the patient with the artificial airway is established once, and meanwhile, the device also completes the process of heating, humidifying and atomizing once, so that the repeated work is realized, the airway of the patient is ensured to be moist, the patient atomization treatment supported by the breathing machine is met, and the positive effect of the airway in the aspect of reducing the pulmonary complications of the patient treated by the breathing machine is realized.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. Intelligent artificial upper respiratory tract device, its characterized in that: the atomizing humidifier comprises an atomizing humidifier body (1), a breathing pipeline body (2), a power supply electric control host (3) and a power supply electric control cable (4), wherein the breathing pipeline body (2) comprises a double-cavity breathing pipeline (201), a threaded pipe joint (202) and a switching elbow (203), the threaded pipe joint (202) and the switching elbow (203) are respectively positioned at two ends of the double-cavity breathing pipeline (201), a semiconductor condensation plate (6) is arranged in the double-cavity breathing pipeline (201), the semiconductor condensation plate (6) divides the inside of the double-cavity breathing pipeline (201) into an air inlet cavity (2011) and an air return cavity (2012), a liquid storage tank (5) is arranged on the side edge of the double-cavity breathing pipeline (201), and the switching elbow (203) is connected to an inlet of the atomizing humidifier body (1); an integrated wire harness plug (102) and an artificial airway joint (101) are arranged on the side edge of the atomizing humidifier main body (1), and a power supply electric control host (3) is connected to the integrated wire harness plug (102) through a power supply electric control cable (4); the medicine storage tank (8) is arranged inside the atomizing humidifier main body (1), an ultrasonic atomizing sheet (803), a medicine adding port (801) and an exhaust port (802) are arranged on the medicine storage tank (8), and the ultrasonic atomizing sheet (803) is opposite to the artificial airway joint (101).

2. The intelligent artificial upper respiratory tract device of claim 1, wherein: an air inlet end (2021) and an air outlet end (2022) are arranged on the inner side of the threaded pipe joint (202), the air inlet end (2021) is communicated with the air inlet cavity (2011), and the air outlet end (2022) is communicated with the air return cavity (2012).

3. The intelligent artificial upper respiratory tract device of claim 1, wherein: the refrigerating surface and the heating surface of the semiconductor condensation plate (6) are respectively positioned in the air return cavity (2012) and the air inlet cavity (2011).

4. The intelligent artificial upper respiratory tract device of claim 1, wherein: the liquid storage tank (5) is positioned on the air return cavity (2012), and the liquid storage tank (5) is detachably fixed on the double-cavity breathing pipeline (201).

5. The intelligent artificial upper respiratory tract device of claim 1, wherein: the medicine storage tank (8) is fixed in the atomizing humidifier main body (1) through a connecting frame, and a medicine adding port (801) and an air outlet (802) of the medicine storage tank (8) are both arranged on the outer side of the atomizing humidifier main body (1).

6. The intelligent artificial upper respiratory tract device of claim 1, wherein: the air inlet cavity (2011) is internally provided with a gas flow sensor (7), and the gas flow sensor (7) is electrically connected with the ultrasonic atomization sheet (803).

7. The intelligent artificial upper respiratory tract device of claim 1, wherein: host data display screen (301) and host function switch (302) are arranged on the power supply electric control host (3), and the power supply electric control host (3) is electrically connected with the gas flow sensor (7), the semiconductor condensation plate (6) and the ultrasonic atomization sheet (803) respectively.