CN219595500U - Medical comprehensive aerosol generator - Google Patents

Abstract

The utility model provides a medical comprehensive aerosol generator, which comprises an atomizer main machine, and is characterized in that: the atomizer host machine include compression pump, vibration pump and air current connecting pipe in casing, the compression pump with the vibration pump is used for exporting jet air flow and vibration air current respectively, set up compression pump air inlet and compression pump outlet on the compression pump, set up vibration pump air inlet and vibration pump outlet on the vibration pump, set up compression pump air current air inlet, compression air current gas outlet, vibration pump air current air inlet, vibration air current gas outlet and switch on the casing, the casing both sides set up air inlet grid and air outlet grid respectively. The atomizer main machine is matched with various atomizing components, so that multiple functions can be realized, the treatment efficiency is high, the repetition and waste of investment of atomizing equipment are reduced, and the atomizing treatment equipment is convenient to maintain and operate.

Description

Medical comprehensive aerosol generator

Technical Field

The utility model belongs to the technical field of medical instruments, relates to an improvement of a medical atomizer technology, and particularly relates to a medical comprehensive aerosol generator.

Background

The aerosol inhalation treatment is an important, effective and widely used treatment method in respiratory system disease treatment, and adopts an atomizer to atomize liquid medicine into tiny particles, and the medicine enters various chambers of respiratory tract and lung to be deposited in a respiratory inhalation mode, so that the purposes of painless, rapid and effective treatment are achieved. Recent studies have shown that aerosol inhalation is also an effective means of vaccination. Vaccination at the mucosal surface of the respiratory tract by nebulized inhalation is more effective and safer than peripheral vaccination. Furthermore, the atomization technique has been attracting attention as a latest generation of nasal cavity cleaning healthcare technique. Compared with other various nasal cavity cleaning technologies, the automatic spray type nasal cavity cleaning device has the advantages of constant pressure, high use comfort, no choking and water inflow of ears, and the like, and even if a child can use the nasal cavity cleaning device with ease.

Although the application scenes of aerosol inhalation therapy and health care are more and more, aerosol inhalation therapy devices on the market at present are often designed only aiming at a specific application scene, for example, aerosol inhalation therapy scenes, nasal cavity cleaning scenes, sinuses deep therapy scenes and the like. The related aerosol inhalation treatment device has the problem of single function. In a real medical environment, different aerosol inhalation treatment and health care operations are often required to be simultaneously or continuously performed, for example, a rhinitis patient needs to perform nasal cavity cleaning before drug treatment and then performing nasal administration treatment. The atomizing equipment of single function to single application scene can't adapt to this requirement, needs medical personnel to change corresponding atomizing treatment equipment constantly according to the scene is different, brings inconvenience for medical operation, leads to the inefficiency of atomizing treatment efficiency. In addition, purchasing different types of single-function atomization treatment equipment for different treatment purposes also causes repetition and waste of atomization equipment investment, and simultaneously introduces a series of problems of complex equipment maintenance, non-uniform equipment operation method, inconsistent accessory specification and the like.

Therefore, how to design a medical comprehensive aerosol generator, a set of atomization treatment equipment can realize multiple functions, has high treatment efficiency, reduces repetition and waste of atomization equipment investment, has simple equipment maintenance and unified equipment operation method, and is a technical problem to be solved in the field at present.

Disclosure of Invention

The utility model aims to solve the problems of the existing atomizer, provides a medical comprehensive aerosol generator, uses an atomizer host machine to be matched with various atomizing components, can realize various functions, has high treatment efficiency, reduces the repetition and waste of the investment of atomizing equipment, and is convenient for maintenance and operation of the atomizing treatment equipment.

The utility model aims at realizing the following technical scheme:

the utility model provides a medical comprehensive aerosol generator, includes atomizer host computer, its characterized in that, atomizer host computer include compression pump, oscillating pump and air current connecting pipe in casing, the compression pump with the oscillating pump is used for exporting jet flow and oscillating air current respectively, set up compression pump air inlet and compression pump air outlet on the compression pump, set up oscillating pump air inlet and oscillating pump air outlet on the oscillating pump, set up compression pump air inlet, compression air outlet, oscillating pump air inlet, oscillating air outlet and switch on the casing, the casing both sides set up air inlet grid and air outlet grid respectively.

The improvement of the technical scheme is as follows: the air inlet, the air outlet, the air inlet and the air outlet of the compression pump are respectively connected with the corresponding first air pipe connector, the corresponding second air pipe connector, the corresponding third air pipe connector and the corresponding fourth air pipe connector through the air flow connecting pipe, so that an air inlet and an air outlet of the compression pump are formed in the atomizer host.

Further improvement of the technical scheme is as follows: the compressor pump air inlet and the oscillating pump air inlet on the control panel are consistent in specification and are of cylindrical concave structures, a raised cylindrical air inlet support is arranged in the center of each cylindrical concave structure, a circular air inlet is formed in the top surface of each cylindrical air inlet support, a plurality of rectangular air inlets are uniformly formed in the side surfaces of each cylindrical air inlet support, and the circular air inlets and the rectangular air inlets form an air inlet channel of the atomizer host.

Further improvement of the technical scheme is as follows: the air inlet of the compressed pump air flow and the air inlet of the oscillating pump air flow on the control panel are both provided with a filter element and an air inlet filter element cover, the filter element is of a hollow tubular structure with a closed bottom surface, the tubular inner diameter and the depth of the filter element are consistent with those of the cylindrical air inlet bracket, the filter element is firmly sleeved on the cylindrical air inlet bracket, and the cylindrical air inlet bracket is covered on the whole surface, so that air entering the air inlet channel is filtered; the filter element cover is of a hollow tubular structure with a closed bottom surface, the tubular outer diameter of the filter element cover is consistent with the inner diameters of the air inlet of the compression pump and the air inlet of the oscillating pump, the filter element cover is embedded in the air inlet of the air flow of the compression pump and the air inlet of the air flow of the oscillating pump, the bottom surface of the filter element cover is slightly larger than the tubular outer diameter of the filter element cover, and a plurality of air inlets are uniformly formed in the bottom surface of the filter element cover.

Further improvement of the technical scheme is as follows: the shell consists of an upper shell and a lower shell, wherein the upper shell is provided with a handle, and the lower shell is provided with a flexible foot pad, a label groove and a plurality of heat dissipation holes; the lower shell is also provided with a power line or a charging port for supplying power to the whole atomizer host, all components and a control panel in the atomizer host are installed and fixed on the lower shell, and the lower shell is also provided with a screw column for connecting and fixing the upper shell; the upper shell is also provided with a medicine cup clamping groove for temporarily placing the atomized medicine cup.

Further improvement of the technical scheme is as follows: the atomizer comprises an atomizer main engine, a compression pump, a gas storage bin, a semi-closed gas storage bin partition board, a gas storage bin air inlet and a gas storage bin air outlet, wherein the gas storage bin is arranged on an air inlet passage of the compression pump in the atomizer main engine, is a hollow cuboid with passivated edges and corners, the bottom of the gas storage bin is provided with a rectangular skirt edge which extends out, screw holes which are uniformly arranged on the rectangular skirt edge are used for fixing the gas storage bin on a lower shell, the top of the gas storage bin is provided with the gas storage bin air inlet and the gas storage bin air outlet which are respectively used for air inlet and air outlet of the gas storage bin, the gas storage bin cavity of the gas storage bin is a closed cavity, gas can only enter and exit from the gas storage bin air inlet and the gas storage bin air outlet, and a semi-closed gas storage bin partition board is arranged on one side of the gas storage bin cavity which is close to the gas storage bin air inlet and used for blocking air flow noise transmitted along the air pipe direction, so that noise generated by the atomizer main engine is reduced; the air storage bin air inlet of the air storage bin is connected with the air inlet of the compression pump on the control panel through an air flow connecting pipe, the air outlet of the air storage bin is connected with the air inlet of the compression pump through an air flow connecting pipe, the air storage bin is used for forming an air storage space on an air inlet passage of the compression pump, and air is absorbed into a cavity of the air storage bin in advance under the action of negative pressure of the air inlet of the compression pump, so that sufficient air input is provided for the compression pump.

Further improvement of the technical scheme is as follows: the atomizer is characterized in that a fan is arranged at one side, close to the air inlet grille, of the atomizer main engine, a spoiler is arranged on the same side plane of the fan, the spoiler consists of a lower shell spoiler and an upper shell spoiler, the lower shell spoiler is integrally manufactured with the lower shell, the upper shell spoiler is integrally manufactured with the upper shell, a circular air passage is formed around the fan, and other airflow passages are sealed. After the air flow enters from the air inlet grille, the air flow is gathered into runoff under the action of the fan, the lower shell spoiler and the upper shell spoiler, enters into an air pump working area of the inner core of the atomizer host, and finally flows out from the air outlet grille, so that the air cooling effect inside the atomizer host is improved.

The first configuration mode of the technical scheme is as follows: the device is characterized in that the atomizer host is provided with an oscillation atomizing cup, an oscillation core, a compressed air inlet and a nasal cavity spray head are arranged on the oscillation atomizing cup, a compressed air outlet of the atomizer host is connected with the compressed air inlet of the oscillation atomizing cup through an air pipe, an oscillation air outlet of the atomizer host is connected with the oscillation core of the oscillation atomizing cup through the air pipe, the jet air provided by the atomizer host is used for atomizing liquid medicine in the oscillation atomizing cup, and the provided oscillation air is used for wrapping atomized aerosol particles generated by the oscillation atomizing cup, so that the aerosol and the oscillation air output by the oscillation atomizing cup are output from the nasal cavity spray head of the oscillation atomizing cup, and deep cleaning and atomization treatment of nasal cavities and nasal sinus cavities are realized.

The second configuration mode of the technical scheme is as follows: the atomizer host is provided with an atomizing cup, the atomizing cup is provided with a compressed air inlet hole and an atomizing outlet, a mouthpiece or a mask is arranged on the atomizing outlet of the atomizing cup, a compressed air outlet of the atomizer host is connected with the compressed air inlet hole of the atomizing cup through an air pipe, and the atomizer host is used for providing jet air to atomize the liquid medicine in the atomizing cup, so that atomized liquid medicine aerosol particles are output from the atomizing outlet of the atomizing cup, and atomization treatment is realized on a patient through the mouthpiece or the mask.

A third configuration mode of the above technical solution: the nose washing cup is arranged on the atomizer host, a spray head and a compressed air inlet hole are formed in the nose washing cup, a compressed air outlet of the atomizer host is connected with the compressed air inlet hole of the nose washing cup through an air pipe, the atomizer host is used for providing jet air to atomize nose washing liquid in the nose washing cup, and atomized nose washing liquid aerosol is output from the spray head of the nose washing cup, so that automatic spray type nasal cavity cleaning is achieved.

Compared with the prior art, the utility model has the following advantages and positive effects:

the medical comprehensive aerosol generator provided by the utility model is matched with various atomizing components by using the main atomizer, so that various functions can be realized, the treatment efficiency is high, the repetition and waste of investment of atomizing equipment are reduced, and the atomizing treatment equipment is convenient to maintain and operate.

Drawings

FIG. 1 is a perspective view of a medical integrated aerosol generator atomizer mainframe of the present utility model;

FIG. 2 is a perspective view of a medical integrated aerosol generator atomizer main frame display bottom surface of the present utility model;

FIG. 3 is a perspective view showing the internal structure of a atomizer main body in a medical integrated aerosol generator according to the present utility model;

FIG. 4 is a partial cross-sectional view of a atomizer main engine showing a fan and a spoiler in a medical integrated aerosol generator according to the present utility model;

FIG. 5 is a cross-sectional view taken along A-A of FIG. 4;

FIG. 6 is a schematic illustration of the connection of a atomizer main unit to an oscillating airflow atomizing cup and a nasal spray in a medical integrated aerosol generator according to the present utility model;

FIG. 7 is a schematic view of the connection structure of the atomizer main unit and the atomizing cup in the medical comprehensive aerosol generator according to the present utility model;

FIG. 8 is a schematic diagram of the connection structure of a nebulizer main unit and a spray type nasal washer in a medical integrated aerosol generator according to the present utility model;

fig. 9 is a perspective view of a nebulizer body gas storage cartridge in a medical integrated aerosol generator according to the utility model.

FIG. 10 is a schematic view of a display bottom surface of a nebulizer body gas storage bin of a medical integrated aerosol generator according to the utility model;

FIG. 11 is a front view of a control panel of a atomizer host in a medical integrated aerosol generator according to the present utility model;

FIG. 12 is a B-B cross-sectional view of FIG. 11;

FIG. 13 is an enlarged schematic view at A in FIG. 12;

fig. 14 is an exploded view of the assembly of the filter cartridge on the control panel of the atomizer mainframe in a medical integrated aerosol generator with the inlet filter cartridge housing of the present utility model.

The reference numerals in the figures are: 1-atomizer main unit, 2-handle, 3-upper housing, 4-lower housing, 5-control panel, 6-air inlet cartridge cover, 7-power switch, 8-compressed air outlet, 9-oscillating air outlet, 10-flexible foot pad, 11-cartridge, 12-medicine cup clamping groove, 13-upper housing air outlet grille, 14-lower housing air outlet grille, 15-upper housing air inlet grille, 16-power cord, 17-fuse holder, 18-tag groove, 19-heat dissipation hole, 20-lower housing air inlet grille, 21-compressed pump, 22-fan, 23-lower housing spoiler, 24-upper housing spoiler, 25-air storage bin, 26-shock pad 27-tracheal male, 28-tracheal, 29-tracheal female, 30-oscillation core, 31-oscillation atomizing cup, 32-atomizing cup, 33-nasal wash cup, 34-airflow connecting pipe, 35-pipeline buckle, 36-compression pump air inlet, 37-compression pump air outlet, 38-oscillation pump air inlet, 39-oscillation pump air outlet, 40-gas storage bin air inlet, 41-gas storage bin air outlet, 42-first gas pipe connecting port, 43-second gas pipe connecting port, 44-third gas pipe connecting port, 45-fourth gas pipe connecting port, 46-air inlet channel, 47-gas storage bin partition plate, 48-gas storage bin cavity, 49-air inlet, 50-oscillation pump and 51-screw column.

Description of the embodiments

This patent is described in further detail below in conjunction with the accompanying drawings:

referring to fig. 1-14, an embodiment of a medical comprehensive aerosol generator according to the present utility model includes an atomizer main unit 1, where the atomizer main unit 1 includes a housing, a compression pump 21, an oscillation pump 50 and an air flow connection pipe 34 in the housing, the compression pump 21 and the oscillation pump 50 are respectively used for outputting an injection air flow and an oscillation air flow, a compression pump air inlet 36 and a compression pump air outlet 37 are provided on the compression pump 21, an oscillation pump air inlet 38 and an oscillation pump air outlet 39 are provided on the oscillation pump, a compression pump air inlet, a compression air outlet 8, an oscillation pump air inlet, an oscillation air outlet 9 and a power switch 7 are provided on the housing, and an air inlet grille and an air outlet grille are provided on two sides of the housing respectively.

Further, a control panel 5 is disposed on the housing, the air inlet of the compressed pump, the air outlet 8 of the compressed air, the air inlet of the oscillating pump, the air outlet 9 of the oscillating air and the power switch 7 are all disposed on the control panel 5, the back of the control panel 5 is provided with a first air pipe connection port 42, a second air pipe connection port 43, a third air pipe connection port 44 and a fourth air pipe connection port 45 corresponding to the air inlet of the compressed pump, the air outlet 8 of the compressed air, the air inlet of the oscillating pump, the air outlet 37 of the oscillating pump, the air inlet 38 of the oscillating pump and the air outlet 39 of the oscillating pump respectively, and the air connection pipe 34 is connected with the corresponding first air pipe connection port 42, second air pipe connection port 43, third air pipe connection port 44 and fourth air pipe connection port 45, so as to form an air inlet and outlet channel in the atomizer host.

As shown in fig. 3, when the air flow connection pipe 34 inside the atomizer main unit 1 is long, the air flow connection pipe can be fixed by using the pipe buckle 35. Acting to prevent the air flow connection tube 34 from loosening and to reduce noise. Shock pads 26 are provided on the compression pump 21 and the oscillation pump 50 for eliminating vibration and noise generated therefrom during operation of the main machine. The shock pad 26 is made of high-elastic rubber and is used for shock absorption and buffering as a whole body of the pump, so that the conduction of vibration is reduced and avoided while the stable operation of the compression pump 21 and the oscillating pump 50 is ensured, and the purposes of shock absorption and noise reduction are achieved.

Still further, as shown in fig. 11-13, the compressed pump air flow inlet and the oscillating pump air flow inlet on the control panel 5 are identical in specification and are both in cylindrical concave structures, a raised cylindrical air inlet support is arranged in the center of each cylindrical concave structure, a circular air inlet is formed in the top surface of each cylindrical air inlet support, a plurality of rectangular air inlets are uniformly formed in the side surfaces of each cylindrical air inlet support, and the circular air inlets and the rectangular air inlets form an air inlet channel 46 of the atomizer host.

Still further, as shown in fig. 12-14, the compressed pump air inlet and the oscillating pump air inlet on the control panel 5 are both provided with a filter element 11 and an air inlet filter element cover 6, the filter element 11 is of a hollow tubular structure with a closed bottom, the tubular inner diameter and depth of the filter element 11 are consistent with those of the cylindrical air inlet bracket, and the filter element 11 is firmly sleeved on the cylindrical air inlet bracket and covers the cylindrical air inlet bracket completely, so as to filter all air entering the air inlet channel 46; the filter core cover 6 is of a hollow tubular structure with a closed bottom surface, the tubular outer diameter of the filter core cover 6 is consistent with the inner diameters of the air inlet of the compressed pump air flow and the air inlet of the oscillating pump air flow, the filter core cover 6 is embedded in the air inlet of the compressed pump air flow and the air inlet of the oscillating pump air flow, the bottom surface of the filter core cover 6 is slightly larger than the tubular outer diameter of the filter core cover, and the filter core cover 6 is convenient to install and detach. A plurality of air inlets 49 are uniformly formed on the bottom surface of the filter element cover 6, and the filter element 11 can be a PE (polyethylene) sintered filter element.

Further, as shown in fig. 1 and 6, the above-mentioned housing is composed of an upper housing 3 and a lower housing 4, the intake grill is composed of an upper housing intake grill 15 and a lower housing intake grill 20, and the outlet grill is composed of an upper housing outlet grill 13 and a lower housing outlet grill 14. The upper shell 3 is provided with a handle 2, and the lower shell 4 is provided with a flexible foot pad 10, a label groove 18 and a plurality of heat dissipation holes 19. The lower shell 4 is also provided with a power line 16 or a charging port for supplying power to the whole atomizer host, all components in the atomizer host 1 and the control panel 5 are fixedly arranged on the lower shell 4, and the lower shell 4 is also provided with a screw column 51 for connecting and fixing the upper shell 3; a medicine cup clamping groove 12 is also arranged on the upper shell 3 and is used for temporarily placing the atomized medicine cup.

As shown in fig. 3, 9 and 10, in order to provide continuous and sufficient input air to meet the working requirement of the compression pump 21, a gas storage bin 25 is arranged on an air inlet passage of the compression pump 21 in the atomizer host 1, the gas storage bin 25 is a hollow cuboid with passivated edges, a rectangular skirt edge extending out is arranged at the bottom of the gas storage bin 25, screw holes uniformly arranged on the rectangular skirt edge are used for fixing the gas storage bin 25 on the lower shell 4, and a gas storage bin air inlet 40 and a gas storage bin air outlet 41 are arranged at the top of the gas storage bin 25 and are respectively used for air inlet and air outlet of the gas storage bin 25. The gas storage bin 25 is fixed on the lower shell 4, the gas storage bin cavity 48 of the gas storage bin 25 is a closed cavity, and gas can only enter and exit from the gas storage bin gas inlet 40 and the gas storage bin gas outlet 41. A semi-closed gas storage partition plate 47 is arranged on one side, close to the gas storage inlet 40, of the gas storage cavity 48 and is used for blocking air flow noise propagating along the air pipe direction, so that noise generated by the operation of the atomizer main unit 1 is reduced.

The air storage bin inlet 40 of the air storage bin 25 is connected with the air inlet of the compression pump on the control panel 5 through the air flow connecting pipe 34, the air storage bin outlet 41 is connected with the air inlet 36 of the compression pump 21 through the air flow connecting pipe 34, the air storage bin 25 is used for forming an air storage space on the air inlet passage of the compression pump 21, and air is absorbed into the air storage bin cavity 48 in advance for storage under the negative pressure of the air inlet 36 of the compression pump 21, so that sufficient air input is provided for the compression pump 21. Since the air flow input by the oscillating pump 50 is smaller, the generated air flow noise is smaller, and the air storage bin 25 is arranged on the air inlet pipeline of the oscillating pump 50, so that the air storage bin is an alternative implementation scheme according to actual needs.

As shown in fig. 3, fig. 4 and fig. 5, on the basis that an air inlet grille and an air outlet grille are used for ventilation and cooling of the atomizer main unit 1 during operation, a fan 22 is arranged at one side, close to the air inlet grille, of the interior of the atomizer main unit 1, a spoiler is arranged on the same side plane of the fan 22, the spoiler is composed of a lower shell spoiler 23 and an upper shell spoiler 24, the lower shell spoiler 23 and the lower shell 4 are integrally manufactured, the upper shell spoiler 24 and the upper shell 3 are integrally manufactured, a circular air passage is formed around the fan 22, and other air flow passages are closed, so that after air flows enter from the air inlet grille, the air flows are collected into runoffs under the action of the fan 22, the lower shell spoiler 23 and the upper shell spoiler 24, enter an air pump working area of the inner core of the atomizer main unit 1, and finally flow out from the air outlet grille, and therefore the air cooling effect of the interior of the atomizer main unit 1 is improved.

The atomizer main machine 1 in the medical comprehensive aerosol generator is provided with different atomization components, so that various medical atomization devices can be formed.

Referring to fig. 6, the atomization device for deep nasal cavity cleaning and treatment of the present utility model is composed of an oscillation atomization cup 31 configured on an atomizer main body 1 in the above medical comprehensive aerosol generator, an oscillation core 30, a compressed air inlet and a nasal cavity spray head are arranged on the oscillation atomization cup 31, a compressed air outlet 8 of the atomizer main body 1 is connected with the compressed air inlet of the oscillation atomization cup 31 through an air pipe 28, an oscillation air outlet 9 of the atomizer main body 1 is connected with the oscillation core 30 of the oscillation atomization cup 31 through the air pipe 28, the jet air provided by the atomizer main body 1 is used for atomizing the liquid medicine in the oscillation atomization cup 31, and the provided oscillation air is used for wrapping the atomized aerosol particles generated by the oscillation atomization cup 31, so that the aerosol and the oscillation air outputted by the oscillation atomization cup 31 are outputted from the nasal cavity spray head of the oscillation atomization cup 31, and deep nasal cavity cleaning and nasal sinus cavity atomization treatment are realized.

Referring to fig. 7, the atomization device for conventional atomization treatment of the present utility model is composed of an atomizer main body 1 in the above medical comprehensive aerosol generator, an atomization cup 32, a compressed air inlet and an atomization outlet are provided on the atomization cup 32, a mouthpiece or a mask is installed on the atomization outlet of the atomization cup 32, the compressed air outlet 8 of the atomizer main body 1 is connected with the compressed air inlet of the atomization cup 32 through an air pipe 28, the atomizer main body 1 is used for providing jet air to atomize the liquid medicine in the atomization cup 32, so that atomized liquid medicine aerosol particles are output from the atomization outlet of the atomization cup 32, and atomization treatment is implemented on a patient through the mouthpiece or the mask.

Referring to fig. 8, the atomization device for conventional atomization treatment of the present utility model is composed of a nose washing cup 33 configured by an atomizer main unit 1 in the above medical comprehensive aerosol generator, the nose washing cup 33 is provided with a spray head and a compressed air inlet hole, a compressed air outlet 8 of the atomizer main unit 1 is connected with the compressed air inlet hole of the nose washing cup 33 through an air pipe 28, the atomizer main unit 1 is used for providing spray air to atomize nose washing liquid in the nose washing cup 33, and the atomized nose washing liquid aerosol is output from the spray head of the nose washing cup 33, so as to realize automatic spray type nasal cavity cleaning.

Specifically: as shown in fig. 3 and fig. 6-8, the connection modes of the air pipes connecting the compressed air outlet 8 and the oscillating air outlet 9 are different, so that the error of the user is avoided. The compressed air outlet 8 is connected with the air pipe male head 27 of the air pipe 28, and the other head, namely the air pipe female head 29 is connected with a compressed air inlet hole of the oscillating atomizing cup 31, the atomizing cup 32 or the nose washing cup 33. The other end of the oscillating airflow outlet 9, namely the air pipe male end 27, is connected with the oscillating core 30 of the oscillating atomizing cup 31, and is connected with the air pipe female end 29 of the air pipe 28.

When the medical comprehensive aerosol generator is particularly used, the atomizer host 1 in the medical comprehensive aerosol generator can be matched with a plurality of medical atomization devices with different functions. As shown in fig. 8, when the nasal cavity needs to be cleaned, the nasal cavity cleaning application can be formed by inserting the male tracheal head 27 of the ventilation pipe 28 matched with the nasal cavity cleaning cup 33 into the compressed air flow outlet 8 of the control panel 5 by using the nasal cavity cleaning cup 33. As shown in fig. 6, when the nasal cavity needs to be subjected to atomization treatment, an oscillation atomization cup 31 is configured, and two attached ventilation pipes 28 are respectively connected with the oscillation atomization cup 31 and an oscillation core 30, and the other ends of the two ventilation pipes 28 are respectively connected with a compressed air flow outlet 8 and an oscillation air flow outlet 9 on the control panel 5, so that deep cleaning and atomization treatment application of the nasal cavity and the nasal sinus cavity is formed. When the respiratory tract atomization treatment application is required, the atomization cup 32 and the ventilation pipe 28 are configured as shown in fig. 7, one end of the ventilation pipe 28 is connected with the atomization cup 32, and the other end is connected with the compressed air flow outlet 8 on the control panel 5, so that the respiratory tract atomization treatment application is formed. As described above, the medical comprehensive aerosol generator provided by the utility model is a comprehensive aerosol generator covering nasal cavity flushing, nasal cavity atomization and respiratory tract atomization, and the three application scenes are realized by matching different medical equipment through the atomizer host 1.

It should be understood that the above description is not intended to limit the utility model to the particular embodiments disclosed, but to limit the utility model to such embodiments, variations, modifications, additions and substitutions are within the scope of the utility model.

Claims (10)

1. The utility model provides a medical comprehensive aerosol generator, includes atomizer host computer, its characterized in that, atomizer host computer include compression pump, oscillating pump and air current connecting pipe in casing, the compression pump with the oscillating pump is used for exporting jet flow and oscillating air current respectively, set up compression pump air inlet and compression pump air outlet on the compression pump, set up oscillating pump air inlet and oscillating pump air outlet on the oscillating pump, set up compression pump air inlet, compression air outlet, oscillating pump air inlet, oscillating air outlet and switch on the casing, the casing both sides set up air inlet grid and air outlet grid respectively.

2. The medical comprehensive aerosol generator according to claim 1, wherein a control panel is arranged on the shell, the air inlet of the compressed pump, the air outlet of the compressed air, the air inlet of the oscillating pump, the air outlet of the oscillating air and the power switch are all arranged on the control panel, the back of the control panel is respectively provided with a first air pipe connection port, a second air pipe connection port, a third air pipe connection port and a fourth air pipe connection port corresponding to the air inlet of the compressed pump, the air outlet of the compressed air pump, the air inlet of the oscillating pump and the air outlet of the oscillating pump, and the air inlet of the air outlet of the oscillating pump are respectively connected with the corresponding first air pipe connection port, the second air pipe connection port, the third air pipe connection port and the fourth air pipe connection port through the air flow connection pipes to form an air inlet and outlet channel in the atomizer host.

3. The medical comprehensive aerosol generator according to claim 2, wherein the air inlet of the compression pump on the control panel is consistent with the air inlet of the oscillating pump in specification and is of a cylindrical concave structure, a raised cylindrical air inlet support is arranged in the center of the cylindrical concave structure, a circular air inlet is formed in the top surface of the cylindrical air inlet support, a plurality of rectangular air inlets are uniformly formed in the side surfaces of the cylindrical air inlet support, and the circular air inlet and the rectangular air inlet form an air inlet channel of a main machine of the atomizer.

4. A medical integrated aerosol generator according to claim 3, wherein the compressed pump air flow inlet and the oscillating pump air flow inlet on the control panel are provided with a filter element and an air inlet filter element cover, the filter element is of a hollow tubular structure with a closed bottom surface, the tubular inner diameter and depth of the filter element are consistent with those of the cylindrical air inlet bracket, the filter element is firmly sleeved on the cylindrical air inlet bracket, and the cylindrical air inlet bracket is covered on the whole surface, so that air which enters the air inlet channel is filtered; the filter element cover is of a hollow tubular structure with a closed bottom surface, the tubular outer diameter of the filter element cover is consistent with the inner diameters of the air inlet of the compression pump and the air inlet of the oscillating pump, the filter element cover is embedded in the air inlet of the air flow of the compression pump and the air inlet of the air flow of the oscillating pump, the bottom surface of the filter element cover is slightly larger than the tubular outer diameter of the filter element cover, and a plurality of air inlets are uniformly formed in the bottom surface of the filter element cover.

5. The medical integrated aerosol generator as set forth in any one of claims 1 to 4, wherein said housing comprises an upper housing and a lower housing, said upper housing having a handle, said lower housing having a flexible foot pad, a label recess, and a plurality of heat dissipating holes; the lower shell is also provided with a power line or a charging port for supplying power to the whole atomizer host, all components and a control panel in the atomizer host are installed and fixed on the lower shell, and the lower shell is also provided with a screw column for connecting and fixing the upper shell; the upper shell is also provided with a medicine cup clamping groove for temporarily placing the atomized medicine cup.

6. The medical comprehensive aerosol generator according to claim 5, wherein a gas storage bin is arranged on an air inlet passage of the compression pump in the atomizer main machine, the gas storage bin is a hollow cuboid with a passivated edge, a rectangular skirt edge extending out is arranged at the bottom of the gas storage bin, uniformly arranged screw holes are formed in the rectangular skirt edge and used for fixing the gas storage bin on the lower shell, a gas storage bin air inlet and a gas storage bin air outlet are formed in the top of the gas storage bin and used for respectively introducing and discharging air from the gas storage bin, the gas storage bin is fixed on the lower shell, a gas storage bin cavity of the gas storage bin is a closed cavity, gas can only enter and exit from the gas storage bin air inlet and the gas storage bin air outlet, and a semi-closed gas storage bin baffle is arranged on one side, close to the gas storage bin air inlet, of the gas storage bin cavity and used for blocking airflow noise transmitted along the air pipe direction, so that noise generated by the operation of the atomizer main machine is reduced; the air storage bin air inlet of the air storage bin is connected with the air inlet of the compression pump on the control panel through an air flow connecting pipe, the air outlet of the air storage bin is connected with the air inlet of the compression pump through an air flow connecting pipe, the air storage bin is used for forming an air storage space on an air inlet passage of the compression pump, and air is absorbed into a cavity of the air storage bin in advance under the action of negative pressure of the air inlet of the compression pump, so that sufficient air input is provided for the compression pump.

7. The medical integrated aerosol generator as set forth in claim 5, wherein a fan is disposed inside the atomizer body adjacent to one side of the air inlet grille, a spoiler is disposed on a plane on the same side as the fan, the spoiler is composed of a lower housing spoiler and an upper housing spoiler, the lower housing spoiler is integrally manufactured with the lower housing, the upper housing spoiler is integrally manufactured with the upper housing, a circular air passage is formed around the fan, and the rest of the air flow passages are closed.

8. The medical integrated aerosol generator as set forth in any one of claims 1 to 4, wherein the atomizer main unit is provided with an oscillation atomizing cup, the oscillation atomizing cup is provided with an oscillation core, a compressed air inlet and a nasal cavity nozzle, a compressed air outlet of the atomizer main unit is connected with the compressed air inlet of the oscillation atomizing cup through an air pipe, an oscillation air outlet of the atomizer main unit is connected with the oscillation core of the oscillation atomizing cup through an air pipe, the jet air provided by the atomizer main unit is used for atomizing the liquid medicine in the oscillation atomizing cup, and the provided oscillation air is used for wrapping the atomized aerosol particles generated by the oscillation atomizing cup, so that the aerosol and the oscillation air outputted by the oscillation atomizing cup are outputted from the nasal cavity nozzle of the oscillation atomizing cup, and deep cleaning and atomization treatment of nasal cavities and sinus cavities are realized.

9. The medical integrated aerosol generator as set forth in any one of claims 1 to 4, wherein the atomizer main unit is provided with an atomizing cup, the atomizing cup is provided with a compressed air inlet hole and an aerosol outlet, a mouthpiece or a mask is mounted on the aerosol outlet of the atomizing cup, the compressed air outlet of the atomizer main unit is connected with the compressed air inlet hole of the atomizing cup through an air pipe, and the atomizer main unit is used for providing jet air to atomize the liquid medicine in the atomizing cup, so that atomized liquid medicine aerosol particles are output from the aerosol outlet of the atomizing cup, and atomized treatment is realized on a patient through the mouthpiece or the mask.

10. The medical integrated aerosol generator as set forth in any one of claims 1 to 4, wherein the atomizer main unit is provided with a nose washing cup, the nose washing cup is provided with a spray head and a compressed air inlet hole, the compressed air outlet of the atomizer main unit is connected with the compressed air inlet hole of the nose washing cup through an air pipe, and the atomizer main unit is used for providing jet air to atomize nose washing liquid in the nose washing cup and enabling atomized nose washing liquid aerosol to be output from the spray head of the nose washing cup so as to realize automatic spray type nasal cavity washing.