Intelligent temperature control atomizing device

Abstract

The utility model relates to atomization device technical field, and disclose an intelligent temperature control's atomization device, including the mist removal subassembly, the bottom of mist removal subassembly is equipped with water tank subassembly, the mist removal subassembly is connected with the mist pipe between water tank subassembly, water tank subassembly electric connection has the plug piece, the end of mist removal subassembly is equipped with temperature control component, the export end of temperature control component is equipped with filter component, and water tank subassembly contains water tank, atomization piece, fan and circuit module, these components cooperate and work and input atomization water vapor to the mist removal subassembly through the mist pipe and spray outward, temperature control component includes the mist removal pass warehouse, the outside fixed sleeve of mist removal pass warehouse has the outer sleeve shell, the outer sleeve shell is equipped with the inner chamber groove, the heating pipe is equipped in the inner chamber groove, the opening end fixed mounting of inner chamber groove has the sealing strip, this device has the function of controlling atomization water vapor temperature, and this device has certain filtration function.

Description

Technical Field

[0001] This utility model relates to the field of atomizing device technology, and more specifically to an intelligent temperature-controlled atomizing device. Background Technology

[0002] To maintain indoor humidity and prevent the indoor environment from becoming too dry, people generally use atomizing devices to humidify the room. Household atomizing humidifiers achieve humidification through the coordinated action of a water tank, atomizing plate, fan, and circuit module. However, atomizing devices still have the following shortcomings in actual use.

[0003] First, existing atomizing devices do not control the temperature of the atomized water vapor produced at the outlet during use. In cold winters, the water vapor produced by atomization can affect the indoor temperature, thereby affecting the comfort of the indoor environment.

[0004] Secondly, when using existing atomizing devices, the water vapor produced by atomization often carries dust and impurity particles, which can easily affect the cleanliness of the environment.

[0005] Therefore, in order to solve the above problems, there is a need to provide an atomizing device with intelligent temperature control. Utility Model Content

[0006] In order to overcome the above-mentioned defects of the prior art, the present invention provides an intelligent temperature-controlled atomizing device to solve the problems existing in the background art.

[0007] To achieve the above objectives, this utility model provides the following technical solution: an intelligent temperature-controlled atomizing device, comprising a mist exhaust component, a water tank component at the bottom of the mist exhaust component, a mist pipe connecting the mist exhaust component and the water tank component, a plug component electrically connected to the water tank component, a temperature control component at the end of the mist exhaust component, a filter component at the outlet end of the temperature control component, and the water tank component including a water tank, an atomizing plate, a fan, and a circuit module. These components work together to input atomized water vapor through the mist pipe to the mist exhaust component and spray it outward.

[0008] Furthermore, the temperature control component includes a de-fogging chamber, an outer shell is fixedly sleeved on the outside of the de-fogging chamber, the outer shell has an inner cavity groove, and a heating tube is provided in the inner cavity groove.

[0009] Furthermore, a sealing strip is fixedly installed at the open end of the inner cavity groove, and the power supply end of the heating tube passes through the sealing strip and is located outside the inner cavity groove.

[0010] Furthermore, a temperature control power supply is fixedly installed on the de-fogging assembly. The temperature control power supply includes a temperature sensor and is electrically connected to the power supply terminal of the heating tube. When the atomized water vapor passes through the de-fogging assembly and is sprayed out from its end, it passes through the de-fogging passage. At this time, the temperature sensor in the temperature control power supply detects the indoor temperature and thereby controls the output voltage of the temperature control power supply, thereby controlling the heating temperature of the heating tube. When the indoor temperature is too low, the temperature sensor can increase the output voltage of the temperature control power supply, thereby increasing the heating threshold of the heating tube. When the indoor temperature is too high, the temperature sensor can decrease the output voltage of the temperature control power supply, thereby decreasing the heating threshold of the heating tube.

[0011] Furthermore, the filter assembly includes an inner rail groove, which is evenly opened on the inner wall of the mist exhaust chamber. Each inner rail groove has a limiting support block at its front end, and a buffer spring is fixedly connected to the limiting support block. The buffer spring is located in the inner rail groove.

[0012] Furthermore, a filter plate is movably sleeved in the inner rail groove, and the outer end of the filter plate is provided with evenly distributed movable support blocks. The movable support blocks are movably sleeved in the inner rail groove, and the end of the buffer spring is fixedly connected to the movable support blocks. The filter plate is provided with evenly distributed filter holes. When the atomized water vapor carries dust and impurity particles, they can be intercepted and filtered by the filter plate, thereby improving the cleanliness of the atomized water vapor. When the atomized water vapor is sprayed out from the inner rail groove, it will give the filter plate a thrust. By setting the inner rail groove and the buffer spring, the filter plate can move, thereby buffering this water vapor thrust.

[0013] The technical effects and advantages of this utility model are as follows:

[0014] 1. This utility model is equipped with a temperature control component. When the atomized water vapor passes through the mist exhaust component and is sprayed out from its end, it will pass through the channel of the mist exhaust chamber. At this time, the temperature sensor in the temperature control power supply detects the indoor temperature and thereby controls the output voltage of the temperature control power supply, thereby controlling the heating temperature of the heating tube. When the indoor temperature is too low, the temperature sensor can increase the output voltage of the temperature control power supply, thereby increasing the heating threshold of the heating tube. When the indoor temperature is too high, the temperature sensor can decrease the output voltage of the temperature control power supply, thereby decreasing the heating threshold of the heating tube. The temperature of the atomized water vapor can be flexibly controlled in the above way.

[0015] 2. This utility model is equipped with a filter component. When the atomized water vapor carries dust and impurity particles, they can be intercepted and filtered by the filter plate, thereby improving the cleanliness of the atomized water vapor. When the atomized water vapor is sprayed out from the inner rail groove, it will give the filter plate a thrust. By setting the inner rail groove and the buffer spring, the filter plate can move, thereby buffering this water vapor thrust and preventing the filter plate from being damaged during long-term use. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0017] Figure 2 This is a schematic diagram of the temperature control component structure of this utility model;

[0018] Figure 3 This is a schematic diagram of the temperature control power supply of this utility model;

[0019] Figure 4 This is a schematic diagram of the structure of the filter assembly of this utility model;

[0020] The attached diagram is labeled as follows: 1. Fog exhaust assembly; 2. Water tank assembly; 3. Fog pipe; 4. Plug; 5. Temperature control assembly; 501. Fog exhaust chamber; 502. Outer shell; 503. Inner cavity groove; 504. Heating tube; 505. Sealing strip; 506. Temperature control power supply; 6. Filter assembly; 601. Inner rail groove; 602. Limiting support block; 603. Buffer spring; 604. Filter plate; 605. Movable support block; 606. Filter hole. Detailed Implementation

[0021] The technical solution of this utility model will be clearly and completely described below with reference to the accompanying drawings. In addition, the forms of the various structures described in the following embodiments are merely illustrative. The intelligent temperature-controlled atomizing device involved in this utility model is not limited to the structures described in the following embodiments. All other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this utility model.

[0022] Reference Figure 1 This utility model provides an intelligent temperature-controlled atomizing device, including a mist exhaust component 1, a water tank component 2 at the bottom of the mist exhaust component 1, a mist tube 3 connecting the mist exhaust component 1 and the water tank component 2, a plug 4 electrically connected to the water tank component 2, a temperature control component 5 at the end of the mist exhaust component 1, and a filter component 6 at the outlet end of the temperature control component 5.

[0023] In this embodiment, when the device is in use, the plug 4 is inserted into the power socket to power the device. The water tank assembly 2 includes a water tank, an atomizing plate, a fan, and a circuit module. These components work together to input atomized water vapor through the mist pipe 3 to the mist exhaust assembly 1 and spray it outward, thereby achieving its atomization effect. Since this part is a conventional technical means used by those skilled in the art, the specific structure and working principle of the water tank assembly 2 will not be described in detail in this embodiment. The temperature control assembly 5 can control the temperature of the atomized water vapor sprayed from it, and the filter assembly 6 can filter impurities from the atomized water vapor, thereby making it cleaner. The specific structure and working principle of this part of the assembly will be described in detail later.

[0024] Reference Figure 2 and Figure 3 The temperature control component 5 includes a de-fogging chamber 501, an outer shell 502 is fixedly sleeved on the outside of the de-fogging chamber 501, the outer shell 502 has an inner cavity groove 503, a heating tube 504 is provided in the inner cavity groove 503, a sealing strip 505 is fixedly installed at the open end of the inner cavity groove 503, the power supply end of the heating tube 504 passes through the sealing strip 505 and is located outside the inner cavity groove 503, and a temperature control power supply 506 is fixedly installed on the de-fogging component 1, the temperature control power supply 506 includes a temperature sensor, and the temperature control power supply 506 is electrically connected to the power supply end of the heating tube 504;

[0025] In this embodiment, when the atomized water vapor passes through the de-mist assembly 1 and is sprayed out from its end, it passes through the channel of the de-mist chamber 501. At this time, the temperature sensor in the temperature control power supply 506 detects the indoor temperature and thereby controls the output voltage of the temperature control power supply 506, thereby controlling the heating temperature of the heating tube 504. When the indoor temperature is too low, the temperature sensor can increase the output voltage of the temperature control power supply 506, thereby increasing the heating threshold of the heating tube 504. When the indoor temperature is too high, the temperature sensor can decrease the output voltage of the temperature control power supply 506, thereby decreasing the heating threshold of the heating tube 504. The temperature of the atomized water vapor can be flexibly controlled in the above manner.

[0026] Reference Figure 4 The filter assembly 6 includes an inner rail groove 601, which is evenly opened on the inner side wall of the mist exhaust chamber 501. Each front end of the inner rail groove 601 is provided with a limiting support block 602. A buffer spring 603 is fixedly connected to the limiting support block 602. The buffer spring 603 is provided in the inner rail groove 601. A filter plate 604 is movably sleeved in the inner rail groove 601. The outer end of the filter plate 604 is provided with evenly distributed movable support blocks 605. The movable support blocks 605 are movably sleeved in the inner rail groove 601. The end of the buffer spring 603 is fixedly connected to the movable support block 605. The filter plate 604 is provided with evenly distributed filter holes 606.

[0027] In this embodiment, when the atomized water vapor carries dust and impurity particles, it can be intercepted and filtered by the filter plate 604, thereby improving the cleanliness of the atomized water vapor. When the atomized water vapor is sprayed out from the inner rail groove 601, it will give the filter plate 604 a thrust. By setting the inner rail groove 601 and the buffer spring 603, the filter plate 604 can move, thereby buffering the thrust of the water vapor and preventing the filter plate 604 from being damaged under long-term use.

[0028] The working principle of this invention is as follows: When the atomized water vapor passes through the mist exhaust assembly 1 and is sprayed out from its end, it passes through the channel of the mist exhaust chamber 501. At this time, the temperature sensor in the temperature control power supply 506 detects the indoor temperature and thereby controls the output voltage of the temperature control power supply 506, thus controlling the heating temperature of the heating tube 504. When the indoor temperature is too low, the temperature sensor can increase the output voltage of the temperature control power supply 506, thereby increasing the heating threshold of the heating tube 504. When the indoor temperature is too high, the temperature sensor can decrease the output voltage of the temperature control power supply 506. The output voltage is reduced, thereby lowering the heating threshold of the heating tube 504. The temperature of the atomized water vapor can be flexibly controlled in this way. When the atomized water vapor carries dust and impurity particles, it can be intercepted and filtered by the filter plate 604, thereby improving the cleanliness of the atomized water vapor. When the atomized water vapor is sprayed out from the inner rail groove 601, it will give the filter plate 604 a thrust. By setting the inner rail groove 601 and the buffer spring 603, the filter plate 604 can move, thereby buffering the thrust of the water vapor and preventing the filter plate 604 from being damaged during long-term use.

[0029] The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. An intelligent temperature-controlled atomizing device, characterized in that, The device includes a mist exhaust assembly (1), a water tank assembly (2) at the bottom of the mist exhaust assembly (1), a mist pipe (3) connecting the mist exhaust assembly (1) and the water tank assembly (2), a plug (4) electrically connected to the water tank assembly (2), a temperature control assembly (5) at the end of the mist exhaust assembly (1), and a filter assembly (6) at the outlet end of the temperature control assembly (5).

2. The intelligent temperature-controlled atomizing device according to claim 1, characterized in that: The temperature control component (5) includes a mist exhaust chamber (501), and an outer shell (502) is fixedly sleeved on the outside of the mist exhaust chamber (501). The outer shell (502) has an inner cavity groove (503), and a heating tube (504) is provided in the inner cavity groove (503).

3. The intelligent temperature-controlled atomizing device according to claim 2, characterized in that: A sealing strip (505) is fixedly installed at the open end of the inner cavity groove (503), and the power supply end of the heating tube (504) passes through the sealing strip (505) and is located outside the inner cavity groove (503).

4. The intelligent temperature-controlled atomizing device according to claim 3, characterized in that: A temperature control power supply (506) is fixedly installed on the demisting component (1). The temperature control power supply (506) includes a temperature sensor and is electrically connected to the power supply terminal of the heating tube (504).

5. The intelligent temperature-controlled atomizing device according to claim 1, characterized in that: The filter assembly (6) includes an inner rail groove (601), which is evenly opened on the inner wall of the mist exhaust chamber (501). Each inner rail groove (601) has a limiting support block (602) at its front end. The limiting support block (602) is fixedly connected to a buffer spring (603), which is located in the inner rail groove (601).

6. The intelligent temperature-controlled atomizing device according to claim 5, characterized in that: A filter plate (604) is movably sleeved in the inner rail groove (601). The outer end of the filter plate (604) is provided with a uniformly distributed movable support block (605). The movable support block (605) is movably sleeved in the inner rail groove (601). The end of the buffer spring (603) is fixedly connected to the movable support block (605). The filter plate (604) is provided with uniformly distributed filter holes (606).

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