TW201507738A - Atomization device matched up with breathing of user - Google Patents

Abstract

The present invention discloses an atomization device matched up with breathing of user, which includes an atomization module, and a control unit and a conversion unit of exhaling atomization and inhaling atomization. The atomization module includes a nozzle sheet and an oscillation sheet. The control unit of exhaling atomization and inhaling atomization records a high inhaling atomization parameter corresponding to an inhaling time parameter for providing a high inhaling atomization amount, and a low exhaling atomization parameter corresponding to an exhaling time parameter for providing a low inhaling atomization amount. The conversion unit of exhaling atomization and inhaling atomization alternately repeats a high exhaling atomization amount and a low exhaling atomization amount. When the atomization module generates a high inhaling atomization amount, the user inhales the high inhaling atomization amount matched up with the negative pressure formed by inhaling: and when the atomization module generates a low exhaling atomization amount, the user rejects inhaling of the low inhaling atomization amount due to the resistance formed by exhaling, so as to reduce the waste of atomization liquid.

Description

Atomizing device with user breathing

The present invention relates to an atomizing device, and more particularly to an atomizing device that cooperates with a user's breathing.

The medical nebulizer is mainly used for treating various upper and lower respiratory diseases. The treatment method mainly uses atomizer to atomize the liquid into tiny particles, and the liquid enters the respiratory tract or enters the lungs by breathing, thereby achieving painlessness. The purpose of rapid and effective treatment.

However, today's atomizing devices continuously atomize the same dose of atomized liquid, and do not consider the frequency of exhalation and inhalation of the human body itself, and adults, children, boys, and girls all have different lung capacity, and the breathing is different. Therefore, the continuous atomization of the same dose of the atomized liquid may cause the atomizing device to continuously atomize the same amount of the atomizing liquid while exhaling, which may cause discomfort and drug utilization rate of the user. Decline.

In view of the above-mentioned problems of the prior art, one of the objects of the present invention is to provide an atomizing device that matches the breathing of the user, and when the atomizing module generates a high inhalation atomization amount, the user absorbs and absorbs the air. The high inspiratory atomization amount is used when the atomization module generates a low expiratory atomization amount to solve the user's exhalation discomfort and reduce the waste of the atomized liquid which is difficult to be absorbed by the user when exhaling.

According to one of the objects of the present invention, an atomizing device that cooperates with a user's breathing includes an atomizing module and a control unit for expiratory atomization and inhalation atomization. The atomization module has a spray orifice and a vibration plate, and the oscillation plate is located on one side of the orifice plate to provide oscillation of the orifice.

The control unit for expiratory atomization and inspiratory atomization records at least one inhalation time parameter, at least one exhalation time parameter, at least one inhalation high atomization parameter, and at least one exhalation low atomization parameter.

The inspiratory high atomization parameter corresponds to the inspiratory time parameter to provide a high inspiratory atomization amount of the atomization module, wherein the high inspiratory atomization amount is 0.01 ml~5 ml per second, and the exhalation low atomization parameter Corresponding to the expiratory time parameter, to provide a low inspiratory atomization amount of the atomization module, wherein the low expiratory aerosolization amount is 0% to 90% of the high expiratory aerosol amount.

The unit of expiratory atomization and inhalation atomization is to repeatedly interlace the high expiratory atomization amount and the low expiratory atomization amount.

When the atomizing module generates a high inspiratory atomization amount, the user can absorb the high inhalation atomization amount when the user forms a negative pressure due to inhalation, and when the atomizing module generates a low expiratory atomization amount, In conjunction with the user's resistance to exhalation, the absorption of low expiratory atomization amount is rejected to reduce the waste of the atomized liquid.

According to one of the objects of the present invention, the orifice sheet is a orifice sheet whose diameter is dynamically changed, and the diameter of the orifice sheet can be dynamically changed to increase the instantaneous atomization amount or reduce the instantaneous atomization amount. Alternatively, the oscillating film is a oscillating piece whose oscillating frequency is dynamically changed, and the oscillating frequency of the oscillating piece can be dynamically changed to increase the instantaneous atomization amount or reduce the instantaneous atomization amount.

According to another object of the present invention, an atomizing device that matches a user's breathing is proposed. A square wave, a sine wave or a triangular wave is generated by dynamically changing the atomization amount per unit time, thereby greatly reducing the clogging of the atomizing liquid in the opening of the orifice sheet, and greatly reducing the clogging of the atomizing liquid in the orifice sheet. Wind-cut noise caused by the opening.

According to still another object of the present invention, an atomizing device that matches a user's breathing is proposed. By adjusting the breathing number adjustment module, the number of breaths per unit time is changed to match the time difference between each user's vital capacity and the difference in breathing depth.

According to still another object of the present invention, an atomizing device that matches a user's breathing is proposed. The atomizing sound and light guiding device has a different sound or a different light, so that the atomizing module guides the user to inhale when the amount of high air intake is atomized, and the atomizing module is low. When the amount of aerosolization is reached, the user is guided to exhale.

1‧‧‧Atomizing device with user breathing

2‧‧‧Atomization module

21‧‧‧High inspiratory atomization

22‧‧‧ low expiratory atomization

23‧‧‧ orifice sheet

231‧‧‧Apertures with dynamically changing caliber

24‧‧‧ Shocking film

241‧‧‧Vibration film with dynamic fluctuation of oscillation frequency

3‧‧‧Control unit for expiratory atomization and inhalation atomization

31‧‧‧ Inhalation time parameters

32‧‧‧Exhalation time parameters

33‧‧‧Inspiratory high atomization parameters

34‧‧‧Expiratory low atomization parameters

35‧‧‧Expulsion unit for expiratory atomization and inhalation atomization

4‧‧‧Atomizing solution

51‧‧‧Enlarge the opening of the orifice

52‧‧‧ Increase the voltage to increase the amplitude of the oscillator

53‧‧‧ Increase the oscillation frequency of the oscillation plate

54‧‧‧Reducing orifice opening

55‧‧‧Reducing the voltage to reduce the amplitude of the oscillator

56‧‧‧Reducing the oscillation frequency of the oscillation plate

6‧‧‧ Breathing frequency adjustment module

7‧‧‧Atomized sound and light guiding device

71‧‧‧ Different voices

72‧‧‧Different light

Figure 1 is the fog of the user's breathing A block diagram of a first embodiment of a chemical device.

Fig. 2A is a schematic diagram of the square wave function of the atomizing device for breathing with the user of the present invention.

Figure 2B is a schematic diagram of the sine wave function of the atomizing device of the present invention.

Figure 2C is a schematic diagram of the triangular wave function of the atomizing device of the present invention.

Figure 3 is a block diagram showing a second embodiment of the atomizing device for breathing with a user of the present invention.

Figure 4 is a block diagram showing a third embodiment of the atomizing device for breathing with a user of the present invention.

Please refer to FIG. 1 , which is a block diagram of the atomizing device for breathing with the user of the present invention. In the figure, the atomizing device 1 for breathing with the user comprises an atomizing module 2, a control unit 3 for expiratory atomization and inhalation atomization, and a conversion unit 35 for expiratory atomization and inhalation atomization.

The atomizing module 2 has an orifice sheet 23 and a vibrating sheet 24, and the vibrating sheet 24 is located on the side of the orifice sheet 23 to provide the orifice sheet 23 to oscillate.

The control unit 3 for expiratory atomization and inhalation atomization controls the atomization module 2 to repeatedly change the high inspiratory atomization amount 21 and the low expiratory atomization amount 22, The control unit 3 for aerosolization and aspiration atomization records at least one inhalation time parameter 31, at least one expiratory time parameter 32, at least one inspiratory high atomization parameter 33, and at least one exhalation low atomization parameter 34.

The inhalation high atomization parameter 33 corresponds to the inhalation time parameter 31 to control the atomization module 2 to provide a high inspiratory atomization amount 21, wherein the high inspiratory atomization amount is 0.01 ml to 5 ml per second, The low gas atomization parameter 34 corresponds to the expiratory time parameter 32 to control the atomization module 2 to control the low expiratory atomization amount 22, wherein the low expiratory atomization amount 22 is 0% of the high inspiratory aerosol amount 21 ~90% ratio.

The inhalation time of the inhalation time parameter 31 or the exhalation time of the exhalation time parameter 32 is between 0.5 and 5 seconds, and is represented by 3 seconds in the embodiment of the present invention, but is not limited thereto.

The expiratory atomization and inspiratory atomization conversion unit 35 alternately interleaves the high expiratory aerosolization amount 21 and the low expiratory aerosolization amount 22.

When the atomizing module 2 generates the high inspiratory atomization amount 21, the user inhales to create a negative pressure in the chest cavity, so that the user absorbs the high inspiratory atomization amount 21; when the atomizing module 2 generates low exhalation When the atomization amount 22 is used, the absorption of the low expiratory atomization amount 22 is repelled by the user to form a resistance to the oral cavity due to exhalation, so as to reduce the waste of the atomization liquid 4.

The orifice sheet 23 can be a orifice plate 231 whose diameter is dynamically changed. The diameter of the orifice sheet 23 can be dynamically changed to increase the instantaneous atomization amount or reduce the instantaneous atomization amount. Or, the shock plate 24 is a shock The oscillating piece 231 whose dynamic frequency changes dynamically can be dynamically changed by the oscillating frequency of the oscillating piece to increase the instantaneous atomization amount or reduce the instantaneous atomization amount.

The oscillating piece 24 is an oscillating piece 241 whose dynamic frequency is oscillated. The oscillating frequency of the oscillating piece can be dynamically changed to increase the instantaneous atomization amount or reduce the instantaneous atomization amount.

Please refer to FIG. 2A~2C, and continue to refer to FIG. 1 , which is a schematic diagram of the square wave, sine wave and triangle wave function of the atomizing device for breathing with the user of the present invention. In the figure, the inhalation high atomization parameter 33 corresponds to the inhalation time parameter 31, and the exhalation low atomization parameter 34 corresponds to the exhalation time parameter 32. The square wave generated by the atomization amount dynamically changes per unit time (eg As shown in Fig. 2A), a sine wave (as shown in Fig. 2B) or a triangular wave (as shown in Fig. 2C), the atomization liquid 4 can be greatly reduced in the opening of the orifice sheet, and the atomization liquid can be greatly reduced. 4 Winding noise caused by the opening of the orifice sheet.

Please refer to FIG. 3, which is a block diagram of a second embodiment of the atomizing device for breathing with the user of the present invention. The difference is that the atomizing device 1 for breathing with the user further includes a breathing number adjusting module 7 for changing the number of breaths per unit time, by adjusting the breathing number adjustment module 6 And changing the inhalation high atomization parameter 33 corresponding to another inhalation time parameter 31 and changing the expiratory low atomization Another exhalation time parameter 32 corresponding to parameter 34 is used to match different users' different lung capacity and different breathing depths.

Please refer to FIG. 4, which is a block diagram showing a third embodiment of the atomizing device for breathing with the user of the present invention. The difference in the figure is that the atomizing device 1 for breathing with the user further comprises an atomizing sound and light guiding device 7 having a different sound 71 or a different light 72, by a different sound 71 or phase. The different light 72 causes the atomizing module 2 to guide the user to inhale when the high inhalation atomization amount 21 is reached, and the atomizing module 2 guides the user to exhale when the low expiratory atomization amount 22 is reached.

1‧‧‧Atomizing device with user breathing

2‧‧‧Atomization module

21‧‧‧High inspiratory atomization

22‧‧‧ low expiratory atomization

23‧‧‧ orifice sheet

24‧‧‧ Shocking film

3‧‧‧Control unit for expiratory atomization and inhalation atomization

31‧‧‧ Inhalation time parameters

32‧‧‧Exhalation time parameters

33‧‧‧Inspiratory high atomization parameters

34‧‧‧Expiratory low atomization parameters

35‧‧‧Expulsion unit for expiratory atomization and inhalation atomization

4‧‧‧Atomizing solution

51‧‧‧Enlarge the opening of the orifice

52‧‧‧ Increase the voltage to increase the amplitude of the oscillator

53‧‧‧ Increase the oscillation frequency of the oscillation plate

54‧‧‧Reducing orifice opening

55‧‧‧Reducing the voltage to reduce the amplitude of the oscillator

56‧‧‧Reducing the oscillation frequency of the oscillation plate

Claims (6)

An atomizing device for absorbing breathing of a user, comprising: an atomizing module having a nozzle plate and a oscillating plate, wherein the oscillating plate is located at a side of the venting plate to provide oscillation of the venting plate; The control unit for expiratory atomization and inhalation atomization records at least one inhalation time parameter, at least one exhalation time parameter, at least one inhalation high atomization parameter and at least one exhalation low atomization parameter, the suction The high gas atomization parameter is a parameter corresponding to the inhalation time to control the atomization module to provide a high inspiratory atomization amount, wherein the high inspiratory atomization amount is 0.01 ml to 5 ml per second. The low-aspiration parameter is a parameter corresponding to the expiratory time to control the atomization module to provide a low expiratory atomization amount, wherein the low expiratory atomization amount is the ratio of the high inspiratory atomization amount 0%~90%; and a conversion unit for expiratory atomization and inhalation atomization, which repeatedly interleaves the high expiratory atomization amount and the low expiratory atomization amount; when the atomization module generates the height When inhaling the atomization amount, the user can inhale to make the chest cavity form a negative pressure state, and absorb the high inspiratory atomization amount, when the atomization mold When the group generates the low expiratory atomization amount, the absorption of the low expiratory atomization amount is rejected by the user's exhalation to cause the oral cavity to form a resistance, thereby reducing the waste of the atomization liquid. The atomizing device for breathing with a user according to the first aspect of the patent application, wherein the orifice film is a orifice plate whose dynamic diameter is changed, and the diameter of the orifice plate can be dynamically changed to increase the moment. The amount of atomization or the amount of instantaneous atomization. The sniffering device is a oscillating piece with a dynamic fluctuation of the oscillating frequency, and the oscillating frequency of the oscillating piece can be dynamically changed to increase the instantaneous fog. Amount or reduce the amount of instantaneous atomization. The atomizing device matched with the user breathing according to the first aspect of the patent application, wherein the inhalation high atomization parameter corresponds to an inhalation time parameter, and the exhalation low atomization parameter corresponds to an expiratory time parameter. The two dynamically generate a square wave, a sine wave or a triangular wave in a unit time, thereby greatly reducing the clogging of the atomizing liquid in the opening of the orifice sheet, and greatly reducing the clogging of the atomizing liquid in the orifice sheet. The wind is cut by the opening. The atomizing device for breathing with the user as described in claim 1 further includes a breathing number adjustment module that changes the number of breaths per unit time by adjusting the number of breaths. The module changes the number of breaths per unit time, and changes the parameter of the inhalation time corresponding to another inhalation time parameter, and changes the parameter of the exhalation low atomization parameter corresponding to another exhalation time to match Each user's lung capacity varies and the breathing depth varies from time to time. The atomizing device for absorbing the user's breathing as described in claim 1 further includes an atomizing sound and light guiding device having a different sound or a different light, by which the difference is The sound or the different light causes the atomizing module to guide the user to inhale during the high inhalation atomization amount, and the atomizing module guides the low expiratory atomization amount The user exhales.