TWM557612U - Atomizer - Google Patents

Abstract

The present invention discloses an atomizer comprising: an atomizer main body, an atomization module, a nozzle structure, a signal transmitter and a signal sensor. The atomization module is disposed inside the atomizer main body, and the atomization module has a plurality of atomization holes. The nozzle structure is assembled on the atomizer main body, and the nozzle structure has a discharge opening corresponding to the plurality of atomization holes. The signal transmitter is used to provide a sensing signal for a plurality of atomizing holes that are directed to the atomizing module. The signal sensor corresponds to the signal transmitter. The sensing signal provided by the signal transmitter passes through the atomization module or is reflected by the atomization module to generate a blocking rate signal, and the signal sensor receives the blocking rate signal to determine the blocking rate of the plurality of atomizing holes.

Description

Nebulizer

The present invention relates to an atomizer, and more particularly to an atomizer capable of determining the blocking rate of an atomizing hole.

The microporous structure inside the existing atomizer for converting the liquid into a mist state and ejecting it will gradually block after long-term use, and the user must disassemble the atomizer parts one by one to view the micropores of the atomizer. The blockage of the structure is cleaned. After the atomizer is disassembled, the obstruction of the micropore structure can be examined through a microscope device or an optical device. However, disassembling the atomizer is likely to damage the parts, which is inconvenient for the average user.

The technical problem to be solved by the present invention is to provide an atomizer capable of determining the blocking rate of the atomizing hole in view of the deficiencies of the prior art.

In order to solve the above technical problem, one of the technical solutions adopted by the present invention is to provide an atomizer comprising: an atomizer main body, an atomization module, a nozzle structure, a signal transmitter and a signal. Sensor. The atomization module is disposed inside the atomizer main body, wherein the atomization module has a plurality of atomization holes. The nozzle structure is assembled on the atomizer main body, wherein the nozzle structure has a discharge opening corresponding to the plurality of atomization holes. The signal transmitter is for providing a sensing signal for a plurality of the atomizing holes that are directed to the atomizing module. The signal sensor corresponds to the signal transmitter. The sensing signal provided by the signal transmitter passes through the atomization module or is reflected by the atomization module to generate a blocking rate signal, and the signal sensor receives the blocking rate signal To judge multiple places The blocking rate of the atomizing hole.

In order to solve the above technical problem, another technical solution adopted by the present invention is to provide an atomizer comprising: an atomizer main body, an atomization module, a nozzle structure, a signal transmitter and a signal. Sensor. The atomization module is disposed inside the atomizer main body, and the atomization module has a plurality of atomization holes. The nozzle structure is assembled on the atomizer host. Wherein, the nozzle structure has a discharge opening corresponding to the plurality of atomization holes. The signal transmitter is for providing a sensing signal for a plurality of the atomizing holes that are directed to the atomizing module. The signal sensor corresponds to the signal transmitter. The atomization module cooperates with the signal sensor to determine the blocking rate of the plurality of atomization holes.

The beneficial effect of the present invention is that the atomizer provided by the present invention can pass through the atomization module or be used by the atomization module by the sensing signal provided by the signal transmitter. Reflecting to generate a blocking rate signal or "the interaction of the signal transmitter and the signal sensor" to determine the blocking rate of a plurality of the atomizing holes.

In order to further understand the features and technical contents of the present invention, please refer to the following detailed description of the present invention and the accompanying drawings. However, the drawings are provided for reference and description only, and are not intended to limit the creation.

D‧‧‧ atomizer

1‧‧‧ atomizer host

2‧‧‧Atomization module

201‧‧‧Atomizing hole

3‧‧‧Nozzle structure

301‧‧‧ spout

4‧‧‧Signal transmitter

5‧‧‧Signal Sensor

S‧‧‧Sensor Module

Fig. 1 is a schematic view showing the function of the atomizer of the first embodiment of the present invention.

2 is a schematic view showing the function of the atomizer of the second embodiment of the present invention.

Fig. 3 is a schematic view showing the function of the atomizer of the third embodiment of the present invention.

Fig. 4 is a schematic view showing the function of the atomizer of the fourth embodiment of the present invention.

The following is a description of an embodiment of the "atomizer" disclosed in the present application by a specific embodiment, and those skilled in the art can understand the advantages and effects of the present invention from the contents disclosed in the specification. This creation can be through other different specific embodiments The details of the present specification can also be applied or modified based on different viewpoints and applications, and various modifications and changes can be made without departing from the spirit of the present invention. In addition, the drawings of the present creation are only for the purpose of simple illustration, and are not stated in advance according to the actual size. The following embodiments will further explain the related technical content of the present invention, but the disclosure is not intended to limit the scope of protection of the present invention.

One of the objects of the present invention is to provide an atomizer capable of determining the blocking rate of an atomizing hole, thereby increasing the convenience of use.

The present invention provides an atomizer D comprising an atomizer host 1, an atomization module 2, a nozzle structure 3, a signal transmitter 4, and a signal sensor 5. The atomization module 2 is disposed inside the atomizer main body 1, and the atomization module 2 has a plurality of atomization holes 201. The nozzle structure 3 is assembled on the atomizer main body 1, and the nozzle structure 3 has a discharge opening 301 corresponding to a plurality of atomizing holes. The signal transmitter 4 is for providing a sensing signal, which is directed to the atomizing module 2. The signal sensor 5 can be set corresponding to the signal transmitter 4. The atomization module 2 can determine the blocking condition of the plurality of atomization holes 201 by the mutual cooperation of the signal transmitter 4 and the signal sensor 5. Alternatively, the sensing signal provided by the signal transmitter 4 can pass through the atomization module 2 or be reflected by the atomization module 2 to generate a blocking rate signal. The signal sensor 5 receives the blocking rate signal to determine the blocking rate of the plurality of atomizing holes 201.

[First Embodiment]

Please refer to FIG. 1, which is a schematic diagram of the function of the atomizer D of the first embodiment of the present invention. The present invention provides an atomizer D comprising an atomizer host 1, an atomization module 2, a nozzle structure 3, a signal transmitter 4, and a signal sensor 5.

In detail, the atomizer main unit 1 constitutes the body of the atomizer D. In actual application, the atomizer main body 1 may include a receiving portion for accommodating an active component of the medicine, and a body portion for electrically controlling the activation of the atomizer D or shut down. The components of the atomizer main unit 1 of the present invention may further be equivalently changed according to actual implementation conditions. It should be noted that the fog shown in Figure 1 The appearance of the chemist D and the atomizer host 1 is intended to be illustrative, not limiting.

Furthermore, the atomization module 2 is disposed inside the atomizer main unit 1. The atomization module 2 has a plurality of atomization holes 201. In actual application, the activation and/or shutdown of the atomization module 2 can be electrically controlled by the electronic components of the body portion. When the atomization module 2 is activated, the atomization module 2 atomizes the medicine in the housing portion.

As described above, the nozzle structure 3 is assembled on the atomizer main unit 1. As shown in FIG. 1, the nozzle structure 3 is assembled on the atomizer main unit 1 and corresponds to the position setting of the atomization module 2. The nozzle structure 3 has a discharge opening 301. When the nozzle structure 3 is assembled on the atomizer main unit 1, the position of the discharge opening 301 corresponds to the position of the plurality of atomization holes 201 of the atomization module 2.

The atomizer D provided by the present invention further includes a signal transmitter 4 and a signal sensor 5. In general, the signal transmitter 4 and the signal sensor 5 can cooperate with each other for judging the blocking condition of the plurality of atomizing holes 201 of the atomizing module 2. A specific way that is feasible is that the signal transmitter 4 provides a sensing signal and directs the sensing signal to the atomizing module 2. After the sensing signal passes through the atomizing module 2, a blocking rate signal is obtained, and the signal sensor 5 receives the blocking rate signal to determine the blocking rate of the plurality of atomizing holes 201.

It is worth mentioning that the manner in which the signal transmitter 4 and the signal sensor 5 of the present invention are arranged can have various implementations. The signal transmitter 4 and the signal sensor 5 may be disposed on the same side of the atomization module 2, or the signal transmitter 4 and the signal sensor 5 may be disposed on opposite sides of the atomization module 2, respectively. It is worth mentioning that. When the signal transmitter 4 and the signal sensor 5 are disposed on the same side of the atomization module 2, the signal transmitter 4 and the signal sensor 5 can form an integral module, such as a sensing module, but are not limited thereto. this.

As shown in FIG. 1, in the first embodiment of the present invention, the signal transmitter 4 and the signal sensor 5 of the atomizer D are disposed on both sides of the atomization module 2, respectively. In detail, the signal transmitter 4 is disposed outside the atomizer D, preferably outside the nozzle structure 3. The signal sensor 5 is disposed inside the atomizer main unit 1, whereby the atomization module 2 is disposed between the signal transmitter 4 and the signal sensor 5. signal The emitter 4 emits a sensing signal from the outside of the nozzle structure 3, and the sensing signal is directly directed to the plurality of atomizing holes 201 of the atomizing module 2 through the ejection opening 301 of the nozzle structure 3. The sensing signal passes through the plurality of atomizing holes 201 to generate a blocking rate signal, and the signal sensor 5 receives the blocking rate signal to determine the blocking rate of the plurality of atomizing holes 201.

As described above, the sensing signal can be an energy wave, a fluid, or a combination of both. For example, the energy wave includes visible light having a specific wavelength, a laser beam, far infrared rays, sound waves, and the like. The fluid may be a gas or liquid that is given a predetermined amount of energy and has a specific momentum, such as a water column or a stream of air. In the present embodiment, the signal transmitter 4 emits an initial fluid having a predetermined momentum. The initial fluid having a predetermined momentum can be emitted by means of high speed high pressure injection. When the initial fluid as the sensing signal is directed to the plurality of atomizing holes 201 of the atomizing module 2, the permeability of the holes of the plurality of atomizing holes 201 determines the amount of fluid passing through the atomizing holes 201. If the atomizer D is in the newly activated state, and the plurality of atomizing holes 201 should be in a clear state, the mass of the initial fluid should be almost equal to the mass of the fluid passing through the plurality of atomizing holes 201; conversely, after long-term use The plurality of atomizing holes 201 of the atomizer D are gradually blocked, and the difference between the mass of the initial fluid and the mass of the fluid having passed through the plurality of atomizing holes 201 is large. A blocking rate signal is generated by the amount of change in the parameter between the fluid passing through the atomizing holes 201 and the initial fluid, and is continuously directed to the signal sensor 5. More specifically, the blocking rate signal may be the amount of momentum change between the initial fluid and the fluid passing through the plurality of atomizing holes 201, the amount of flow change, or the impulse received per unit area of the signal sensor 5 ( That is the pressure). For example, if the pressure received by the signal sensor 5 is smaller, it can be inferred that the blocking rate of the plurality of atomizing holes 201 is higher. Therefore, the signal sensor 5 can determine the blocking rate of the plurality of atomizing holes 201 through the blocking rate signal.

[Second embodiment]

Please refer to FIG. 2 , which is a schematic diagram of the function of the atomizer D of the second embodiment of the present invention. The present invention provides an atomizer D comprising an atomizer host 1, an atomization module 2, a nozzle structure 3, a signal transmitter 4, and a signal sensor 5.

The second embodiment of the present invention differs from the first embodiment in that the signal sensor 5 of the second embodiment is disposed outside the atomizer D, preferably outside the nozzle structure 3. The signal transmitter 4 is disposed inside the atomizer main unit 1, whereby the atomization module 2 is disposed between the signal transmitter 4 and the signal sensor 5.

The signal transmitter 4 provides a sensing signal and directs the sensing signal from the atomizer main unit 1 to the atomizing module 2. After the sensing signal passes through the atomizing module 2, a blocking rate signal is generated, and the signal sensor 5 receives the blocking rate signal to determine the blocking rate of the plurality of atomizing holes 201.

As with the first embodiment described above, the sensing signal of the present embodiment may be an energy wave, a fluid, or a combination of both. For example, the energy wave includes visible light having a specific wavelength, a laser beam, far infrared rays, sound waves, and the like. The fluid may be a gas or liquid that is given a predetermined amount of energy and has a specific momentum, such as a water column or a stream of air. For detailed principles, refer to the description of the first embodiment, and details are not described herein again.

[Third embodiment]

Please refer to FIG. 3 , which is a schematic diagram of the function of the atomizer D of the third embodiment of the present invention. The present invention provides an atomizer D comprising an atomizer host 1, an atomization module 2, a nozzle structure 3, a signal transmitter 4, and a signal sensor 5.

The signal transmitter 4 and the signal sensor 5 of the present embodiment are both disposed inside the atomizer main body 1 and located on the same side of the atomization module 2. In this embodiment, the signal transmitter 4 and the signal sensor 5 constitute a sensing module S. Similarly, the signal transmitter 4 emits a sensing signal, which is sent to the atomizing module 2, and generates a blocking rate signal through the reflection of the atomizing module 2, and the signal sensor 5 receives the blocking rate. The blocking rate of the plurality of atomizing holes 201 of the atomizing module 2 is judged by the signal.

In detail, in the present embodiment, the signal transmitter 4 emits a visible laser beam having a specific wavelength, for example, green laser light having a wavelength of 520 nm. The sensing signal (initial laser light) is directed to the atomizing module 2 and its plurality of atomizing holes 201. The principle is to generate a blocking rate signal by using the reflectivity of the plurality of atomizing holes 201 against the laser light. specific In other words, if the atomizer D is newly activated, the plurality of atomizing holes 201 should be in a clear state, and the reflectance of the laser beam is low, the intensity of the reflected light is low, and the blocking rate signal should be small. When the signal sensor 5 receives a small blocking rate signal, it can be judged that the blocking rate of the plurality of atomizing holes 201 should be low. On the contrary, if the smoothness of the plurality of atomizing holes 201 gradually decreases after the atomizer D is used for a period of time, when the signal emitter 4 emits a laser beam to the atomizing module 2, the laser beam passes through the plurality of fogs. The surface of the aperture 201 is reflected, and the intensity of the reflected beam can be used as a blocking rate signal, and the blocking rate signal can be received by the signal sensor 5, thereby judging the blocking condition of the plurality of atomizing holes 201.

[Fourth embodiment]

Please refer to FIG. 4 , which is a schematic diagram of the function of the atomizer D of the fourth embodiment of the present invention. The present invention provides an atomizer D comprising an atomizer host 1, an atomization module 2, a nozzle structure 3, a signal transmitter 4, and a signal sensor 5.

The signal transmitter 4 and the signal sensor 5 of this embodiment are both located on the same side of the atomization module 2. The difference between this embodiment and the third embodiment is that the signal transmitter 4 and the signal sensor 5 of the present embodiment are both disposed outside the atomizer D, in other words, the outside of the nozzle structure 3, and corresponding thereto. The position setting of the atomization module 2. Similarly, the signal transmitter 4 and the signal sensor 5 of the embodiment can constitute a sensing module S. The signal transmitter 4 emits a sensing signal, which is directed to the atomizing module 2 through the ejection opening 301 of the nozzle structure 3. Specifically, the signal transmitter 4 emits a green laser beam and directs it to the plurality of atomizing holes 201 of the atomization module 2. Similarly, the intensity of the reflected beam after the laser beam is reflected by the surface of the plurality of atomizing holes 201 forms a blocking rate signal. The signal sensor 5 accepts the blocking rate signal, thereby determining the blocking rate of the plurality of atomizing holes 201.

[Advantageous Effects of Embodiments]

The beneficial effect of the present invention is that the nebulizer D provided by the present invention can pass through the atomization module 2 or be atomized by the sensing signal provided by the signal transmitter 4. The module 2 is reflected to generate a blocking rate signal or a mutual cooperation between the signal transmitter 4 and the signal sensor 5 to determine the blocking rate of the plurality of atomizing holes 201.

The above disclosure is only a preferred and feasible embodiment of the present invention, and is not intended to limit the scope of the patent application of the present invention. Therefore, any equivalent technical changes made by using the present specification and the contents of the drawings are included in the application for this creation. Within the scope of the patent.

Claims (10)

An atomizer comprising: an atomizer main body; an atomization module disposed inside the atomizer main body, wherein the atomization module has a plurality of atomization holes; a nozzle structure And being assembled on the atomizer main body, wherein the nozzle structure has a discharge opening corresponding to the plurality of atomization holes; and a signal transmitter for providing a projection to the atomization module a sensing signal of the plurality of atomizing holes; and a signal sensor corresponding to the signal transmitter; wherein the sensing signal provided by the signal transmitter passes through the atomizing mode The group is reflected by the atomization module to generate a blocking rate signal, and the signal sensor receives the blocking rate signal to determine a blocking rate of the plurality of atomizing holes. The atomizer of claim 1, wherein one of the signal transmitter and the signal sensor is disposed inside the atomizer host, the signal transmitter and the Another one of the signal sensors is disposed external to the nebulizer host, and the blocking rate signal is generated by the sensing signal passing through the atomizing module. The atomizer according to claim 1, wherein the signal transmitter and the signal sensor are both disposed inside the atomizer main body and located on the same side of the atomization module, and The blocking rate signal is generated by the sensing signal being reflected by the atomizing module. The atomizer of claim 1, wherein the signal transmitter and the signal sensor are both disposed outside the atomizer main body and located on the same side of the atomization module, and The blocking rate signal is generated by the sensing signal being reflected by the atomizing module. The atomizer of claim 1, wherein the sensing signal is an energy wave, a fluid, or a combination thereof. An atomizer comprising: an atomizer main body; an atomization module disposed inside the atomizer main body, wherein the atomization module has a plurality of atomization holes; a nozzle structure And being assembled on the atomizer main body, wherein the nozzle structure has a discharge opening corresponding to the plurality of atomization holes; and a signal transmitter for providing a projection to the atomization module a sensing signal of the plurality of atomizing holes; and a signal sensor corresponding to the signal transmitter; wherein the atomizing module passes through the signal transmitter and the signal sensor Cooperating with each other to determine the blocking rate of a plurality of the atomizing holes. The atomizer of claim 6, wherein one of the signal transmitter and the signal sensor is disposed inside the atomizer host, the signal transmitter and the Another one of the signal sensors is disposed external to the nebulizer host. The atomizer of claim 6, wherein the signal transmitter and the signal sensor are both disposed inside the atomizer host and on the same side of the atomization module. The atomizer of claim 6, wherein the signal transmitter and the signal sensor are both disposed outside the atomizer main body and on the same side of the atomization module. The atomizer of claim 6, wherein the sensing signal is an energy wave, a fluid, or a combination thereof.