The present invention provides an atomization equipment. Specifically, the atomization equipment may add liquid automatically and reduce the waste of atomization.
For atomization technology, it has always been closely related to human life. For example, many people need to cool down both indoor and outdoor environments in summer. Especially for outdoor environments, it is common method for cooling with atomized water.
In addition to the needs of water mist for cooling, an alternative use which is quite important is directed to disinfection and sterilization in personal daily life. Especially, if there is a simple device that can automatically generate disinfectant water mist while specific infectious diseases are rapidly spread during certain period, it will be quite convenient.
However, the commercial atomization equipment often has several disadvantages. The first drawback is that the atomized water mist is not uniform enough that may cause a lot of water mist to be released directly in the form of liquid without becoming mist, wasting a lot of liquid. In addition, the container carrying the liquid cannot automatically replenish the liquid, resulting in the device needs to be replenished manually and frequently, which is quite inconvenient to use.
Therefore, there is an urgent need for an atomization equipment that can automatically replenish liquid stably and release water mist in a uniform and non-wasting liquid form.
In order to solve the problems mentioned in the prior art, the present invention provides an atomization equipment which comprise a lid and a shell.
The lid is configured with a plurality of gas chambers, and the shell engages with the lid. The shell comprises a plurality of windows, a tank, at least one vibrator, a liquid input, a liquid stopper and at least one blower. The windows match and communicate with the gas chambers, and at least one vibrator is configured at bottom of the tank. The liquid input is configured on the side wall of the tank. The liquid stopper be detachably closed the liquid input. At least one blower communicates with the tank.
The above-mentioned descriptions are only preferred embodiments of the present invention and are not intended to limit the scope of implementation of the present invention. Therefore, all the shapes, structures, features, and spirits described in the scope of the patent application of the present invention shall be regarded as equivalent to the changes and modifications per se, and be included in the scope of the patent application of the present invention.
To make the description of the present disclosure more detailed and complete, the following description provides an illustrative description for the implementation and specific embodiments of the present invention. However, the following description is not the only form of implementing or using specific embodiments of the invention. In these paragraphs, the features of various specific embodiments are covered as well as the method steps and sequences for constructing and operating these specific embodiments. However, the other embodiments may also be utilized to achieve the same or equivalent function and sequence of steps.
As shown in
Specifically, this embodiment of the present invention provides an atomization equipment 10. The shape of the atomization equipment 10 is a square cube. The atomization equipment 10 of this embodiment comprises the lid 100 and the shell 200. The shell 200 comprises a plurality of window 201, tank 202, vibrator 203, liquid input 204, liquid stopper 205, and blower 206. Although we see two blowers in the cross section. Actually, there are four blowers in this embodiment because blowers are configured on the side of tank 202 in pairs. The blower 206 is connected to the tank 202 by aligning. In addition, two blowers on the left side are configured to be clamped to the liquid input 204, and the liquid input 204 is configured on the side wall of the tank 202.
The blower 206 of this embodiment may is a gas pump. The liquid input 204 is main used for adding liquid. Specifically, the liquid input 204 of this embodiment further connect to the liquid supply source. The liquid supply source can be a spare liquid bottles, cans, or barrels, etc. and can be a connecting pipe with outer supply liquid.
In the embodiment, the lid 100 and shell 200 are made of acrylic acid, and more precisely transparent acrylic acid. In this embodiment, we can easily realize the inner operation condition of the atomization equipment 10 due to the transparency of acrylic acid. The user can quickly find the malfunction part of the atomization equipment 10.
In the embodiment, there are a plurality of gas chambers 101 configured on the lid 100, and the shell 200 engages with the lid 100. As shown in
Specifically, the gas chamber 101 of this embodiment also includes the inclined plate 102a and the inclined plate 102b. The inclined plate 102a is configured on a way of the air outlet. The inclined plate 102b is configured on the top of a channel between gas chamber 101 and window 201. Specifically, inclined plate 102a and inclined plate 102b can assist condensation liquid generated on the channel which slid down into tank 202 by gravity which can reduce greatly waste liquid from condensed and not atomizing.
As shown in
Moreover, the liquid stopper 205 of this embodiment be detachably closed the liquid input 204. The liquid stopper 205 of this embodiment is constructed by pivot joint 2051, connecting unit 2052, sealing plate 2053, and float 2054. The quantity of float 2054 could be changed by needs.
The pivot joint 2051 of this embodiment is configured on the lower of the liquid input 204. The pivot joint 2051 could be a pivot pin configured on the plates. The connecting unit 2052 is connected rotationally to the pivot joint 2051. In this embodiment, the connecting unit 2052 is formed by two side plates. Two side plates clamp the pivot joint 2051 which is the axis of the rotation that can make the connecting unit 2052 can be rotated by the center (such as pivot joint 2051) for a certain distance.
Therefore, the sealing plate 2053 of this embodiment is configured on the connecting unit 2052 and is used for closing the liquid input 204. The sealing plate 2053 can be made of waterproof materials such as rubber or silicone because sealing plate 2053 of this embodiment has to impact the liquid input 204 and achieve sealing from water.
Finally, the float 2054 of this embodiment is fixed to the side of the connecting unit 2052, and the sealing plate 2053 is fixed to the other side of the connecting unit 2052. When the liquid level L of tank 202 changes, the position of float 2054 will be changed which makes sealing plate 205 rotate, and liquid input 204 will be opened.
As shown in
As shown in
As time passes, the liquid is changed to mist M continuously which makes the position of liquid level L drop. Dropped liquid level L drives float 2054 will be rotated which makes connecting unit 2052 and sealing plate 2053 be rotated in a clockwise direction. As sealing plate 2053 rotates to leave away liquid input 204. Hence, liquid input 204 will be opened without blocking from sealing plate 2053, and liquid input 204 refill new liquid to tank 202 as dotted allow shown in
After liquid level L is raised to a default level, float 2054 will be rotated to drive sealing plate 2053 rotate in counterclockwise direction by connecting to connecting unit 2052 and the rotation makes sealing plate 2053 close liquid input 204. The design structure in this embodiment makes the tank 202 be refilled liquid automatically.
In the embodiment, the microcontroller and microprocessor of the mechanical-electric driving device further can connect to an infrared sensor or optical sensor. When the sensor detecting a specific object or fit the specific condition, vibrator 203 will be turn on to atomize.
Further, the present invention provides a function for adding liquid to the liquid level manually. As shown in
As shown in
The water container 300 of this embodiment further comprises a plugged-inlet 301 protruding from the water container 300. The plugged-inlet 301 is a tube that connects to the water container 300 and whose outer shape can be a cylinder, rectangular prism, polygonal prism, etc. Hence, the shapes of the refilled water inlet 207 are designed for matching to the shape of the plugged inlet 301 which makes them paired with each other by the female and male connecting way.
Accordingly, the user can take any leakless approach to fill the water container 300 through the plugged inlet 301 (i.e. the water container 300 is placed with the plugged inlet 301 facing upwards). After the water container 300 is full, the user places the water container 300 upsides down, and makes the plugged inlet 301 align to the refilled water inlet 207, and then the water container 300 will fill into the atomization equipment automatically. The aligned direction is like the arrow shown in
Specifically, the plugged inlet 301 can be designed to include a valve whose window way is turning to a specific angle in order to avoid leaking when the water container 300 upsides down. Refilled water inlet 207 also can be a valve. The user can be refilled by the design of plugged inlet 301 on the water container 300.
As shown in
The above-mentioned descriptions are only preferred embodiments of the present invention and are not intended to limit the scope of implementation of the present invention. Therefore, all the shapes, structures, features, and spirits described in the scope of the patent application of the present invention shall be regarded as equivalent to the changes and modifications per se, and be included in the scope of the patent application of the present invention.
Number | Date | Country | Kind |
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111204091 | Apr 2022 | TW | national |