CN117258088A - Atomized inhalation treatment equipment for pediatric pneumonia - Google Patents

Abstract

The invention belongs to the technical field of pediatric pneumonia atomization inhalation treatment, and particularly discloses a pediatric pneumonia atomization inhalation treatment device which comprises a medicine atomizer, an atomization tube, an aggregation type hanging flow medicine conveying mechanism and a top pressure type cavity changing mechanism, wherein the atomization tube is communicated with an atomization output end of the medicine atomizer, the aggregation type hanging flow medicine conveying mechanism is arranged on one side of the atomization tube far away from the medicine atomizer, the top pressure type cavity changing mechanism is arranged on two sides of the aggregation type hanging flow medicine conveying mechanism, and the aggregation type hanging flow medicine conveying mechanism comprises a double tight sealing mechanism and a medicine inhalation mechanism. The invention provides the aerosol inhalation treatment equipment for the pediatric pneumonia, which can increase the inhalation amount of medicine mist for children, avoid excessive loss of the medicine mist, reduce the aerosol treatment duration, and guide and collect the medicine mist to be flowed into the air.

Description

Atomized inhalation treatment equipment for pediatric pneumonia

Technical Field

The invention belongs to the technical field of pediatric pneumonia aerosol inhalation treatment, and particularly relates to aerosol inhalation treatment equipment for pediatric pneumonia.

Background

At present, paediatrics are comprehensive medical science for comprehensively researching physical and mental development, health care and disease prevention and treatment of the children in the period, and all the health and sanitation problems related to the children and teenagers in the period belong to the paediatrics range; the subject treated is in the growth stage; pneumonia refers to inflammation of the terminal airways, alveoli and pulmonary interstitium, and can be caused by pathogenic microorganisms such as bacteria, viruses, fungi, atypical pathogens and other physical and chemical factors such as radioactive rays, inhaled foreign matters and the like, so that children need to be treated by adopting an atomization mode.

The existing aerosol inhalation treatment at present has the following problems:

the existing atomization adsorption mask is provided with a large air vent, so that medicine mist which is conveyed into the mask is not inhaled by children, a large amount of medicine mist flows out of the mask, so that when the children perform atomization treatment, little part of medicine mist is inhaled by the children, most of medicine mist flows into the outside air, the atomization treatment time is prolonged, the atomization treatment efficiency is reduced, and secondly, the medicine mist flowing into the air also causes harm to eyes of a wearer who is performing atomization treatment, therefore, the medicine mist inhalation amount of the children is increased, excessive loss of the medicine mist is avoided, the atomization treatment duration is reduced, and the pneumonia atomization inhalation treatment equipment for collecting the medicine mist which is about to flow into the air in a diversion manner can be provided.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the scheme provides the aerosol inhalation treatment equipment for the pediatric pneumonia, which can increase the inhalation amount of the medicine aerosol for children, avoid excessive loss of the medicine aerosol, reduce the aerosol treatment duration and guide and collect the medicine aerosol to be flown into the air.

The utility model provides a be used for paediatrics pneumonia atomizing inhalation therapy equipment, including medicine atomizer, atomizing pipe, gathering type suspension flow drug delivery mechanism and top die type cavity change mechanism, atomizing pipe intercommunication is located medicine atomizer's atomizing output, gathering type suspension flow drug delivery mechanism locates the one side that the medicine atomizer was kept away from to the atomizing pipe, top die type cavity change mechanism locates gathering type suspension flow drug delivery mechanism both sides, gathering type suspension flow drug delivery mechanism includes two closely sealing mechanism and medicine inhalation mechanism, two closely sealing mechanism locates the one side that the medicine atomizer was kept away from to the atomizing pipe, medicine inhalation mechanism locates two closely sealing mechanism lateral walls, top die type cavity change mechanism includes accuse flow discharge mechanism and diffusion guide mechanism, accuse flow discharge mechanism locates two closely sealing mechanism both sides, diffusion guide mechanism locates accuse flow discharge mechanism both ends.

As a further preferable scheme, the double-tight sealing mechanism comprises a sealing ring, a face mask, a locking plate and a cylindrical elastic belt, wherein the sealing ring is arranged on one side of the atomizing pipe, which is far away from the medicine atomizer, the face mask is arranged on one side of the sealing ring, which is close to the atomizing pipe, a plurality of groups of locking plates are arranged on the side wall of the sealing ring, the cylindrical elastic belt is arranged between the locking plates, and the cylindrical elastic belt is arranged on one side of the locking plate, which is far away from the face mask; the medicine inhalation mechanism comprises a three-way joint, a shunt tube, a narrow channel tube, a one-way air inlet valve, a medicine delivery tube and a hedging spray head, wherein the three-way joint is arranged on one side of the mask away from the sealing ring, one side of the atomizing tube away from the medicine atomizer is communicated with the side wall of the three-way joint, the shunt tube is arranged on two sides of the three-way joint in an up-down communicated mode, the narrow channel tube is communicated with one side of the shunt tube away from the three-way joint, the one-way air inlet valve is communicated with the side wall of the narrow channel tube, the medicine delivery tube is arranged between one side of the narrow channel tube away from the shunt tube and the mask, the upper wall and the bottom wall of the mask are symmetrically arranged up-down, one end of the medicine delivery tube away from the narrow channel tube is penetrated inside the mask, the hedging spray head is communicated with one side of the medicine delivery tube close to the mask, and the hedging spray head is oppositely arranged.

During the use, the face guard is emboliaed children's mouth nose position through the elasticity extension of barrel-type elastic webbing, sealing ring and children's body skin laminating, the one end that the medicine atomizer was kept away from to the atomizing pipe is inserted inside the tee bend joint, tee bend joint and medicine atomizer are switched on through the connection of atomizing pipe, at this moment, liquid medicine with the configuration is poured into inside the medicine atomizer, the medicine atomizer atomizes the medicine, liquid medicine after the atomizing is the gaseous inflow inside the atomizing pipe, the atomizing pipe shunts the medicine fog to the shunt tubes inside through the tee bend joint, because the internal diameter of narrow passageway pipe is less than the internal diameter of shunt tubes and medicine delivery pipe, the medicine fog of shunt tubes inside is by thick taper, accelerate the velocity of flow of medicine fog, can produce low pressure near the medicine fog of high-speed flow, the pressure inside the narrow passageway pipe reduces, outside air enters into the narrow passageway intraduct under the unidirectional flow of unidirectional air inlet valve, for the inside the face guard, the air enters into the medicine delivery pipe inside along with the flow of medicine fog, the medicine fog that the medicine pipe will mix with air is through the shower nozzle blowout, set up the medicine fog relatively, make the medicine fog of spraying nozzle flow into shunt tubes, because the internal diameter of shunt tubes is less than shunt tubes, the internal diameter of the inside the shunt tubes, the internal diameter of medicine fog, the medicine fog is mutually impacted and the medicine fog has the large to the medicine fog that the two bundles of medicine fog has the impact and has the large impact on the middle part when the medicine fog is carried out, and the medicine fog is greatly the person and has the medicine and has the impact and has the medicine fog and the medicine and has the impact and the medicine and has the impact to the medicine and the medicine fog.

Preferably, the flow control discharging mechanism comprises a discharging pipe, a flow control cavity, a fixed magnetic plate, hollow magnetic balls and a circulation cavity, wherein a plurality of groups of the discharging pipes are communicated with each other and arranged at two sides of the mask, the flow control pipe is communicated with one side of the discharging pipe far away from the mask, the flow control cavity is arranged in the flow control pipe, the fixed magnetic plate is arranged on the inner wall of the middle part of the flow control cavity, the circulation cavity is symmetrically arranged in the flow control pipes at two sides of the fixed magnetic plate, the circulation cavity is arranged in the flow control pipe between the discharging pipes, the flow control cavity is arranged in the flow control pipe at one side of the flow control cavity far away from the fixed magnetic plate, the inner diameter of the flow control cavity is gradually increased from one end close to the circulation cavity, the hollow magnetic balls are arranged at one end of the flow control cavity close to the circulation cavity, the fixed magnetic plate and the hollow magnetic balls are arranged in different polarities, the hollow magnetic balls are adsorbed by magnetic force, and the hollow magnetic balls are fixedly arranged at the inner wall of one end of the flow control cavity close to the fixed magnetic plate; the diffusion prevention flow guiding mechanism comprises a flow guiding ball cylinder, flow guiding ports, a water absorbing cotton layer, a flow guiding pipe, a flow guiding cotton layer and a water softening cotton layer, wherein the flow guiding ball cylinder is communicated with two sides of the flow controlling pipe, a plurality of groups of flow guiding ports are formed in the side wall of the flow guiding ball cylinder, the water absorbing cotton layer is arranged inside the flow guiding ball cylinder, the flow guiding pipe penetrates through the locking plate and is communicated between the cylinder type elastic belt and the flow guiding ball cylinder, the water softening cotton layer is arranged inside the cylinder type elastic belt, and the flow guiding cotton layer is arranged between the water softening cotton layer and the water absorbing cotton layer.

When the medical fog mask is used, the medical fog in the mask can be discharged when reaching a certain pressure, the medical fog in the mask flows into the flow control cavity through the discharge pipe, the medical fog enters the flow control cavity, the pressure of the medical fog in the flow control cavity is larger than the suction force of the fixed magnetic plate on the hollow magnetic ball, the medical fog pushes the hollow magnetic ball to move towards one end of the flow control pipe, which is close to the guide ball cylinder, along with the movement of the hollow magnetic ball, the inner diameter of the flow control cavity is gradually increased, the diameter of the hollow magnetic ball is unchanged, a gap is formed between the flow control cavity and the hollow magnetic ball, the medical fog flows into the guide ball cylinder through the gap between the flow control cavity and the hollow magnetic ball, the water vapor in the medical fog is adsorbed by the water absorption cotton layer in the guide ball cylinder, the discharge amount of the medical liquid in the medical fog is reduced, the damage of the medical liquid to eyes of children is effectively avoided, and the medical liquid adsorbed by the water absorption cotton layer is guided into the water cotton layer, so that the medical liquid is stored in the water cotton layer, and the storage volume is increased.

The beneficial effect that this scheme of adoption above-mentioned structure obtained is as follows:

compared with the prior art, this scheme adopts the accuse flow to medicine fog emission, on the one hand, can make the person of wearing inhale more medicine fog as far as possible, be convenient for to the treatment of disease, on the other hand, reduce the emission flow of medicine fog, the more problem that causes the damage to the person's eyes of discharging of medicine fog has effectually been avoided, the inside medicine fog of face guard flows into accuse flow intracavity portion through the discharge tube, medicine fog enters into circulation intracavity portion, the inside medicine fog of circulation intracavity portion is greater than the fixed magnetic plate and is used for the suction of hollow magnetic ball, the medicine fog promotes the hollow magnetic ball and is close to the one end of water conservancy diversion ball section of thick bamboo to the accuse flow tube and remove, along with the removal of hollow magnetic ball, the internal diameter of accuse flow chamber increases gradually, the diameter of hollow magnetic ball is unchangeable, the clearance between accuse flow chamber and the hollow magnetic ball is used to the medicine fog, the inside water vapor in the water absorption cotton layer of water conservancy diversion ball section of thick bamboo adsorbs the medicine fog, reduce the emission of medicine liquid in the medicine fog.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present solution;

FIG. 2 is a front perspective view of the present solution;

FIG. 3 is a bottom perspective view of the present solution;

FIG. 4 is a front view of the present solution;

FIG. 5 is a left side view of the present solution;

FIG. 6 is a right side view of the present solution;

FIG. 7 is a top view of the present solution;

FIG. 8 is a partial cross-sectional view of section A-A of FIG. 5;

FIG. 9 is a partial cross-sectional view of B-B of FIG. 7;

FIG. 10 is a partial cross-sectional view of the C-C of FIG. 7;

fig. 11 is an enlarged structural view of the portion I of fig. 1.

The medicine atomizer comprises a medicine atomizer body 1, a medicine atomizer 2, an atomizing pipe 3, an aggregation type hanging flow medicine delivery mechanism 4, a double tight sealing mechanism 5, a sealing ring 6, a face mask 7, a locking plate 8, a cylinder type elastic belt 9, a medicine suction mechanism 10, a three-way joint 11, a shunt pipe 12, a narrow channel pipe 13, a one-way air inlet valve 14, a medicine delivery pipe 15, a hedging spray head 16, a top pressure type cavity changing mechanism 17, a flow control discharge mechanism 18, a discharge pipe 19, a flow control pipe 20, a flow control cavity 21, a fixed magnetic plate 22, a hollow magnetic ball 23, an anti-diffusion flow guide mechanism 24, a flow guide ball cylinder 25, a flow guide port 26, a water absorption cotton layer 27, a flow guide pipe 28, a flow guide cotton layer 29, a water soft cotton layer 30 and a flow cavity.

The accompanying drawings are included to provide a further understanding of the present disclosure and are incorporated in and constitute a part of this disclosure, illustrate and do not limit the disclosure.

Detailed Description

The technical solutions in the embodiments of the present solution will be clearly and completely described below with reference to the drawings in the embodiments of the present solution, and it is apparent that the described embodiments are only some embodiments of the present solution, but not all embodiments; all other embodiments, based on the embodiments in this solution, which a person of ordinary skill in the art would obtain without inventive faculty, are within the scope of protection of this solution.

In the description of the present embodiment, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate orientation or positional relationships based on those shown in the drawings, merely to facilitate description of the present embodiment and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be configured and operated in a particular orientation, and thus should not be construed as limiting the present embodiment.

As shown in fig. 1-11, the treatment equipment for pediatric pneumonia atomization inhalation provided by the scheme comprises a medicine atomizer 1, an atomization tube 2, an aggregation type hanging flow medicine conveying mechanism 3 and a top pressure type cavity change mechanism 16, wherein the atomization tube 2 is communicated with an atomization output end of the medicine atomizer 1, the aggregation type hanging flow medicine conveying mechanism 3 is arranged on one side of the atomization tube 2 away from the medicine atomizer 1, the top pressure type cavity change mechanism 16 is arranged on two sides of the aggregation type hanging flow medicine conveying mechanism 3, the aggregation type hanging flow medicine conveying mechanism 3 comprises a double tight sealing mechanism 4 and a medicine suction mechanism 9, the double tight sealing mechanism 4 is arranged on one side of the atomization tube 2 away from the medicine atomizer 1, the medicine suction mechanism 9 is arranged on the side wall of the double tight sealing mechanism 4, the top pressure type cavity change mechanism 16 comprises a flow control discharge mechanism 17 and a diffusion prevention flow guide mechanism 23, the flow control discharge mechanism 17 is arranged on two sides of the double tight sealing mechanism 4, and the diffusion prevention flow guide mechanism 23 is arranged on two ends of the flow control discharge mechanism 17.

The double-tight sealing mechanism 4 comprises a sealing ring 5, a face mask 6, a locking plate 7 and a cylindrical elastic belt 8, wherein the sealing ring 5 is arranged on one side of the atomizing tube 2 far away from the medicine atomizer 1, the face mask 6 is arranged on one side of the sealing ring 5 close to the atomizing tube 2, a plurality of groups of locking plates 7 are arranged on the side wall of the sealing ring 5, the cylindrical elastic belt 8 is arranged between the locking plates 7, and the cylindrical elastic belt 8 is arranged on one side of the locking plate 7 far away from the face mask 6; the medicine inhalation mechanism 9 comprises a three-way joint 10, a shunt tube 11, a narrow channel tube 12, a one-way air inlet valve 13, a medicine delivery tube 14 and a hedging spray head 15, wherein the three-way joint 10 is arranged on one side of the mask 6 far away from the sealing ring 5, one side of the atomization tube 2 far away from the medicine atomizer 1 is communicated with the side wall of the three-way joint 10, the shunt tube 11 is vertically communicated with two sides of the three-way joint 10, the narrow channel tube 12 is communicated with one side of the shunt tube 11 far away from the three-way joint 10, the one-way air inlet valve 13 is communicated with the side wall of the narrow channel tube 12, the medicine delivery tube 14 is communicated with the upper wall and the bottom wall of the mask 6, one end of the medicine delivery tube 14 far away from the narrow channel tube 12 is penetrated inside the mask 6, the hedging spray head 15 is communicated with one side of the medicine delivery tube 14 near the mask 6, and the hedging spray head 15 is oppositely arranged.

The flow control and discharge mechanism 17 comprises discharge pipes 18, flow control pipes 19, flow control cavities 20, fixed magnetic plates 21, hollow magnetic balls 22 and a circulation cavity 30, wherein a plurality of groups of the discharge pipes 18 are communicated and arranged on two sides of the mask 6, the flow control pipes 19 are communicated and arranged on one side, far away from the mask 6, of the discharge pipes 18, the flow control cavities 20 are arranged in the flow control pipes 19, the fixed magnetic plates 21 are arranged on the inner wall of the middle part of the flow control cavities 20, the circulation cavity 30 is symmetrically arranged in the flow control pipes 19 on two sides of the fixed magnetic plates 21, the circulation cavities 30 are arranged in the flow control pipes 19 between the discharge pipes 18, the flow control cavities 20 are arranged in the flow control pipes 19 on one side, far away from the fixed magnetic plates 21, of the circulation cavity 20 are gradually increased from one end, close to the circulation cavity 30, the hollow magnetic balls 22 are arranged on one end, close to the circulation cavity 30, of the fixed magnetic plates 21 and the hollow magnetic balls 22 are arranged in a heteropolar manner, and the hollow magnetic balls 22 are fixedly arranged on the inner wall, close to the fixed magnetic plates 21, of the flow control cavities 20; the diffusion prevention flow guiding mechanism 23 comprises a flow guiding ball cylinder 24, a flow guiding opening 25, a water absorbing cotton layer 26, a flow guiding pipe 27, a flow guiding cotton layer 28 and a water softening cotton layer 29, wherein the flow guiding ball cylinder 24 is communicated with two sides of the flow controlling pipe 19, a plurality of groups of flow guiding openings 25 are arranged on the side wall of the flow guiding ball cylinder 24, the water absorbing cotton layer 26 is arranged inside the flow guiding ball cylinder 24, the flow guiding pipe 27 penetrates through the locking plate 7 and is communicated between the cylinder type elastic belt 8 and the flow guiding ball cylinder 24, the water softening cotton layer 29 is arranged inside the cylinder type elastic belt 8, and the flow guiding cotton layer 28 is arranged between the water softening cotton layer 29 and the water absorbing cotton layer 26.

In specific use, in the first embodiment, the mask 6 is elastically stretched and sleeved on the mouth and nose parts of the child through the cylindrical elastic belt 8, the water soft cotton layer 29 arranged in the cylindrical elastic belt 8 is elastically stretched along with the elastic stretch, the water soft cotton layer 29 has the characteristics of good water absorption and good rebound resilience, the sealing ring 5 is attached to the skin of the child, one end of the atomizing tube 2, which is far away from the medicine atomizer 1, is inserted into the three-way joint 10, and the three-way joint 10 is connected with the medicine atomizer 1 through the connection of the atomizing tube 2;

specifically, the configured liquid medicine is injected into the medicine atomizer 1, the medicine atomizer 1 is opened to atomize the configured medicine, the atomized liquid medicine flows into the atomizing pipe 2 in a gaseous state, the atomizing pipe 2 shunts the medicine mist into the shunt pipe 11 through the three-way joint 10, and when the medicine mist in the shunt pipe 11 flows through the inside of the narrow-way pipe 12, the medicine mist is thinned by thick, the flow speed of the medicine mist is accelerated, low pressure is generated near the medicine mist flowing at high speed, so that the pressure in the narrow-way pipe 12 is reduced, and the outside air enters the inside of the narrow-way pipe 12 under the unidirectional flow of the unidirectional air inlet valve 13 to provide air for the inside of the mask 6;

the inhaled air enters the medicine delivery pipe 14 along with the flow of the medicine mist, the medicine mist mixed with the air is sprayed out by the medicine delivery pipe 14 through the opposite-flushing spray heads 15, the sprayed medicine mist is mutually impacted by the opposite-flushing spray heads 15, when the medicine mist is impacted, as the two medicine mist layers have certain impact force, the two medicine mist layers block the advancing paths of the medicine mist layers, the medicine mist layers are gradually gathered in the middle part of the mask 6, the concentration of the medicine mist layers is increased after the medicine mist layers are gathered, the inhalation quantity of a wearer to the medicine mist layers is greatly increased, and the problem of medicine mist waste is effectively avoided;

under the premise of ensuring the concentration of the medicine mist in the mask 6, the medicine mist reaching a certain pressure in the mask 6 is discharged, in an initial state, the hollow magnetic ball 22 is positioned at one end of the flow control cavity 20 close to the flow control cavity 30, the magnetic attraction of the fixed magnetic plate 21 to the hollow magnetic ball 22 is greater than the gravity born by the hollow magnetic ball 22, the diameter of the hollow magnetic ball 22 is greater than the inner diameter of the flow control cavity 30, the hollow magnetic ball 22 is positioned in the flow control cavity 20 at one side of the flow control cavity 30 close to the flow guide ball cylinder 24, and the flow control cavity 30 is in a blocking and cutting-off state;

when the medicine mist in the mask 6 flows into the flow control cavity 20 through the discharge pipe 18, the medicine mist enters the flow control cavity 30, the pressure of the medicine mist in the flow control cavity 30 is larger than the suction force of the fixed magnetic plate 21 on the hollow magnetic ball 22, the medicine mist pushes the hollow magnetic ball 22 to move towards one end of the flow control pipe 19, which is close to the flow guide ball cylinder 24, along with the movement of the hollow magnetic ball 22, the inner diameter of the flow control cavity 20 is gradually increased, a gap is formed between the flow control cavity 20 and the hollow magnetic ball 22 due to the fact that the diameter of the hollow magnetic ball 22 is unchanged, the medicine mist flows into the flow guide ball cylinder 24 through the gap between the flow control cavity 20 and the hollow magnetic ball 22, the water vapor in the medicine mist is adsorbed by the water absorption cotton layer 26 in the flow guide ball cylinder 24, the discharge amount of medicine liquid in the medicine mist is reduced, damage to eyes of children by the medicine liquid is effectively avoided, the medicine liquid absorbed by the water absorption cotton layer 26 is guided into the water soft cotton layer 29, the storage volume of the medicine liquid is increased, and inhalation treatment of children is completed; repeating the operation when the product is used next time.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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

The present embodiment and the embodiments thereof have been described above with no limitation, and the embodiment shown in the drawings is merely one of the embodiments of the present embodiment, and the actual structure is not limited thereto. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the technical solution.

Claims (9)

1. An aerosol inhalation treatment device for pediatric pneumonia, comprising a drug atomizer (1) and an atomization tube (2), characterized in that: still include gathering type and hang and flow medicine conveying mechanism (3) and top die type cavity change mechanism (16), atomizing output of drug atomizer (1) is located in atomizing pipe (2) intercommunication, gathering type hangs and flow medicine conveying mechanism (3) and locates one side that drug atomizer (1) was kept away from in atomizing pipe (2), top die type cavity change mechanism (16) are located gathering type and hang and flow medicine conveying mechanism (3) both sides, gathering type hangs and flow medicine conveying mechanism (3) including two closely seal mechanism (4) and drug inhalation mechanism (9), two closely seal mechanism (4) are located atomizing pipe (2) and are kept away from one side of drug atomizer (1), drug inhalation mechanism (9) are located two closely seal mechanism (4) lateral wall, top die type cavity change mechanism (16) include accuse and flow discharge mechanism (17) and prevent that diffusion guide mechanism (23) are located two closely seal mechanism (4) both sides, prevent that diffusion guide mechanism (23) locate accuse and flow discharge mechanism (17) both ends.

2. A nebulized inhalation therapy device for pediatric pneumonia according to claim 1, characterized in that: the double-tight sealing mechanism (4) comprises a sealing ring (5), a face mask (6), a lock plate (7) and a barrel-shaped elastic belt (8), wherein the sealing ring (5) is arranged on one side of an atomizing pipe (2) away from a medicine atomizer (1), the face mask (6) is arranged on one side of the sealing ring (5) close to the atomizing pipe (2), a plurality of groups of the lock plates (7) are arranged on the side wall of the sealing ring (5), the barrel-shaped elastic belt (8) is arranged between the lock plates (7), and the barrel-shaped elastic belt (8) is arranged on one side of the lock plate (7) away from the face mask (6).

3. A nebulized inhalation therapy device for pediatric pneumonia according to claim 2, characterized in that: the medicine inhalation mechanism (9) comprises a three-way joint (10), a shunt tube (11), a narrow-channel tube (12), a one-way air inlet valve (13), a medicine delivery tube (14) and a hedging spray head (15), wherein the three-way joint (10) is arranged on one side of the mask (6) away from the sealing ring (5), one side of the medicine atomizer (1) is communicated with the side wall of the three-way joint (10) and is arranged on the side wall of the three-way joint (10), the shunt tube (11) is communicated with the two sides of the three-way joint (10) up and down, and the narrow-channel tube (12) is communicated with the shunt tube (11) and is arranged on one side of the shunt tube (11) away from the three-way joint (10).

4. A nebulized inhalation therapy device for pediatric pneumonitis according to claim 3, characterized in that: the one-way air inlet valve (13) is communicated with the side wall of the narrow channel pipe (12), the medicine delivery pipe (14) is communicated between one side, far away from the shunt pipe (11), of the narrow channel pipe (12) and the mask (6), the medicine delivery pipe (14) is vertically symmetrically arranged on the upper wall and the bottom wall of the mask (6), one end, far away from the narrow channel pipe (12), of the medicine delivery pipe (14) is penetrated inside the mask (6), the opposite flushing spray nozzle (15) is communicated with one side, close to the mask (6), of the medicine delivery pipe (14), and the opposite flushing spray nozzle (15) is oppositely arranged.

5. A nebulized inhalation therapy device for pediatric pneumonia according to claim 4, characterized in that: the flow control and discharge mechanism (17) comprises discharge pipes (18), flow control pipes (19), a flow control cavity (20), a fixed magnetic plate (21), hollow magnetic balls (22) and a flow cavity (30), wherein a plurality of groups of the discharge pipes (18) are communicated with one another and are arranged on two sides of the face mask (6), and the flow control pipes (19) are communicated with one side, far away from the face mask (6), of the discharge pipes (18).

6. A nebulized inhalation therapy device for pediatric pneumonia according to claim 5, characterized in that: the flow control cavity (20) is arranged inside the flow control pipe (19), the fixed magnetic plate (21) is arranged on the inner wall of the middle part of the flow control cavity (20), the flow control pipes (19) on two sides of the fixed magnetic plate (21) are symmetrically arranged in the flow control cavity (30), and the flow control cavity (30) is arranged inside the flow control pipe (19) between the discharge pipes (18).

7. A nebulized inhalation therapy device for pediatric pneumonia according to claim 6, characterized in that: the utility model discloses a magnetic control flow device, including fixed magnetic plate (21), hollow magnetic ball (22), accuse flow chamber (20), flow control chamber (20) are located inside accuse flow tube (19) that fixed magnetic plate (21) one side was kept away from in circulation chamber (30), and accuse flow chamber (20) internal diameter is the incremental situation by the one end that is close to circulation chamber (30) begins, and its cavity internal diameter increases gradually, the one end that accuse flow chamber (20) is close to circulation chamber (30) is located to hollow magnetic ball (22), and fixed magnetic plate (21) and hollow magnetic ball (22) are different extremely setting, and fixed magnetic plate (21) adsorb hollow magnetic ball (22) through magnetic force, and hollow magnetic ball (22) are fixed to be set up at the one end inner wall that accuse flow chamber (20) is close to fixed magnetic plate (21).

8. A nebulized inhalation therapy device for pediatric pneumonia according to claim 7, characterized in that: the diffusion prevention flow guide mechanism (23) comprises a flow guide ball cylinder (24), flow guide openings (25), a water absorption cotton layer (26), a flow guide pipe (27), a flow guide cotton layer (28) and a water softening cotton layer (29), wherein the flow guide ball cylinder (24) is communicated with two sides of the flow control pipe (19), and a plurality of groups of flow guide openings (25) are formed in the side wall of the flow guide ball cylinder (24).

9. A nebulized inhalation therapy device for pediatric pneumonia according to claim 8, characterized in that: the cotton layer (26) absorbs water and locates inside water conservancy diversion ball section of thick bamboo (24), honeycomb duct (27) run through lock board (7) intercommunication and locate between barrel-type elastic belt (8) and water conservancy diversion ball section of thick bamboo (24), the cotton layer (29) of gentle cotton of water locates inside barrel-type elastic belt (8), cotton layer (28) of water conservancy diversion is located between cotton layer (29) and the cotton layer (26) absorbs water.