CN113289162A - Test-started nano water mist manufacturing device and method - Google Patents

Abstract

The invention discloses a test-started nano water mist manufacturing device and method, which comprises the following steps: air mass sensor, main control panel, heating chamber, atomizer chamber, dry combustion chamber and respiratory mask, air mass sensor detect the surrounding environment air quality, and air mass sensor is connected with the main control panel, and air mass sensor's testing result sends to the main control panel, and the heating chamber communicates with atomizer chamber, dry combustion chamber respectively, is provided with the heater in the heating chamber, be provided with the heating wire in the dry combustion chamber, be provided with the atomizing piece in the atomizer chamber, the main control panel is connected with heater, heating wire and atomizing piece respectively, controls the running state of heater, heating wire and atomizing piece, the respiratory mask passes through the gas-supply pipe and is connected with the atomizer chamber, is connected with the dry combustion chamber through the muffler, and the main control panel controls the operation of whole device and stops according to the testing result. The invention solves the problems that the existing nano water mist manufacturing equipment has small atomizing amount and can not be started according to the test of environmental conditions.

Description

Test-started nano water mist manufacturing device and method

Technical Field

The invention relates to the technical field of nano water mist manufacturing, in particular to a test-started nano water mist manufacturing device and method.

Background

There are four types of atomization methods that are common at present: electrospray atomization, pressure atomization, rotary disc atomization and ultrasonic atomization. Wherein the atomization amount of the electrospray atomization is too small, and the atomization rate is lower than 0.1 mL/h; pressure atomization can cause uncomfortable noise; the atomization particle diameter of the rotary disc atomization is too large and exceeds 100 mu m, and the atomization amount is small. Although some ultrasonic atomizers appear in the market at present, the ultrasonic atomizers have small atomization amount and large power consumption because the generated water mist is not heated, and a large amount of water mist is lost in the water mist transportation process, so that the atomization effect is poor. And the atomization control is difficult to form a unified and centralized control mode, and the atomization effect is poor.

And the existing nanometer water mist manufacturing equipment can not judge whether to start according to the environmental condition, is easily influenced by the external environment, and causes the concentration of the produced nanometer water mist to be impure and mixed with impurity components.

Disclosure of Invention

Therefore, the invention provides a test-started nano water mist manufacturing device and method, and aims to solve the problems that the existing nano water mist manufacturing equipment is small in atomization amount and cannot be started according to environmental conditions.

In order to achieve the above purpose, the invention provides the following technical scheme:

according to a first aspect of the present invention, there is disclosed a test-enabled nano-water mist production apparatus, the apparatus comprising: air mass sensor, main control panel, heating chamber, atomizer chamber, dry combustion chamber and respiratory mask, air mass sensor detects the surrounding environment air quality, and air mass sensor is connected with the main control panel, and air mass sensor's testing result sends main control panel, the heating chamber communicates with atomizer chamber, dry combustion chamber respectively, be provided with the heater in the heating chamber, be provided with the heating wire in the dry combustion chamber, be provided with the atomizing piece in the atomizer chamber, the main control panel is connected with heater, heating wire and atomizing piece respectively, controls the running state of heater, heating wire and atomizing piece, the respiratory mask passes through the gas-supply pipe and is connected with the atomizer chamber, is connected with the dry combustion chamber through the muffler, and the main control panel controls the operation of whole device and stops according to the testing result

Further, the air quality sensor includes: formaldehyde detects sensor, PM2.5 and detects sensor, temperature and humidity sensor, formaldehyde detects sensor, PM2.5 and detects sensor, temperature and humidity sensor and all is connected with the main control board, and formaldehyde content, PM2.5 content, temperature, humidity data send to the main control board in the air that will detect.

Furthermore, the atomizing chamber, the heating chamber and the dry burning chamber are sequentially arranged in the atomizing shell, the atomizing chamber, the heating chamber and the dry burning chamber are separated by partition plates, the top of the atomizing chamber is open, and gas can freely circulate.

Further, the inside atomizing piece that installs of atomizer chamber, the atomizing piece is connected with the main control board, adds water in the atomizer chamber, and the atomizing piece vibrates and produces nanometer water smoke.

Further, install the heater in the heating chamber, the heater is connected with the control mainboard, the control mainboard control heater generates heat, and the water injection in the heating chamber makes steam through the heat that the heater produced.

Further, a heating wire and a fan are installed in the dry combustion chamber, the heating wire and the fan are both connected with a main control panel, the heating wire heats air, the fan blows hot air to promote the circulation of gas, and the main control panel controls the heating temperature of the heating wire and the air speed of the fan.

Further, the atomizing chamber top is connected with the gas-supply pipe, the gas-supply pipe is connected to the air inlet of respiratory mask, dry combustion chamber lateral wall is connected with the muffler, the gas outlet of breathing out the suction nozzle is connected to the muffler.

Furthermore, the main control board is a central control device, controls the vibration amplitude of the atomizing sheet, the temperature of the heater and the heating wire and the rotating speed of the fan, adjusts the air supply and suction speed and the concentration of the corresponding solution component in the air, and controls whether the atomizing sheet, the heater, the heating wire and the fan work or not according to the detection result of the air quality sensor.

According to a second aspect of the invention, a test-started nano water mist manufacturing method is disclosed, and the method comprises the following steps:

the formaldehyde detection sensor, the PM2.5 detection sensor and the temperature and humidity sensor are used for respectively detecting the formaldehyde content, the PM2.5 content and temperature and humidity data in the air;

the main control board receives the data obtained by detection, judges whether the harmful components in the air exceed the standard or not, and controls each device to work if the harmful components do not exceed the standard;

heating purified water in the heating chamber by using a heater to generate water vapor;

the atomizing sheet is used for high-frequency slapping purified water in the atomizing chamber to generate nano-scale water mist;

heating the air in the dry burning room by using an electric heating wire;

mixing the water vapor, the nano-scale water mist and the heated air by using a fan and pushing the mixture to a breathing mask;

and introducing the mixed gas in the respirator into a dry burning chamber through a gas return pipe for cyclic utilization.

The invention has the following advantages:

the invention discloses a test starting nanometer water mist manufacturing device and method, which respectively detect formaldehyde content, PM2.5 content, temperature and humidity data in air through a formaldehyde detection sensor, a PM2.5 detection sensor and a temperature and humidity sensor, judge whether the standard requirements are met, and start can be carried out only after the standard is met, so that the quality of nanometer water mist is ensured. The main control panel controls each electric appliance part, so that centralized and unified control is realized, the atomization process is closer to the actual requirement, and personalized adjustment is performed. The nanoscale water mist is generated through the atomizing sheet, and the noise generated in the working process of the atomizing equipment is reduced. The nanoscale water mist manufacturing equipment generates nanoscale water mist through high-frequency vibration of the atomizing plates, so that the atomizing rate of the atomizing equipment is improved. In addition, the water mist generated by the atomizing plate is nano-scale water mist, so the particle size of the water mist generated by the nano-scale water mist manufacturing equipment is smaller and more uniform compared with the water mist generated by the rotary disc atomizing equipment. The plurality of atomizing sheets are adopted to generate the nano-scale water mist, and the generated nano-scale water mist, the water vapor and the hot air are mixed to improve the temperature of the nano-scale water mist, so that the loss of the nano-scale water mist in the transportation process is reduced, and the atomizing amount of the nano-scale water mist manufacturing equipment is increased.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structures, ratios, sizes, and the like shown in the present specification are only used for matching with the contents disclosed in the specification, so as to be understood and read by those skilled in the art, and are not used to limit the conditions that the present invention can be implemented, so that the present invention has no technical significance, and any structural modifications, changes in the ratio relationship, or adjustments of the sizes, without affecting the effects and the achievable by the present invention, should still fall within the range that the technical contents disclosed in the present invention can cover.

FIG. 1 is a flow chart of a test-initiated nano water mist manufacturing method according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a test-enabled nano water mist manufacturing apparatus according to an embodiment of the present invention;

in the figure: 1-heating chamber, 2-atomizing chamber, 3-dry burning chamber, 4-respirator, 11-water filling port, 12-heater, 21-atomizing sheet, 31-blower, 32-gas pipe, 33-air return pipe and 34-electric heating wire.

Detailed Description

The present invention is described in terms of particular embodiments, other advantages and features of the invention will become apparent to those skilled in the art from the following disclosure, and it is to be understood that the described embodiments are merely exemplary of the invention and that it is not intended to limit the invention to the particular embodiments disclosed. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

Referring to fig. 2, the present embodiment discloses a test-enabled nano water mist manufacturing apparatus, which includes: an air quality sensor, a main control panel, a heating chamber 1, an atomizing chamber 2, a dry burning chamber 3 and a breathing mask 4, the air quality sensor detects the air quality of the surrounding environment, the air quality sensor is connected with the main control panel, the detection result of the air quality sensor is sent to the main control panel, the heating chamber 1 is respectively communicated with the atomizing chamber 2 and the dry burning chamber 3, a heater 12 is arranged in the heating chamber 1, the dry burning chamber 3 is internally provided with a heating wire 34, the atomizing chamber 2 is internally provided with an atomizing plate 21, the main control panel is respectively connected with the heater 12, the heating wire 34 and the atomizing sheet 21 to control the running states of the heater 12, the heating wire 34 and the atomizing sheet 21, the respiratory mask 4 is connected with the atomizing chamber 2 through the air pipe 32, the main control panel controls the operation and stop of the whole device according to the detection result.

The air quality sensor includes: formaldehyde detects sensor, PM2.5 and detects sensor, temperature and humidity sensor, formaldehyde detects sensor, PM2.5 and detects sensor, temperature and humidity sensor and all is connected with the main control board, and formaldehyde content, PM2.5 content, temperature, humidity data send to the main control board in the air that will detect. And the main control board judges whether the air quality reaches the standard according to the detection result, so that the starting or the closing of each device is controlled.

The nano-scale water mist manufacturing equipment has the advantages of low noise, high atomization speed and large atomization amount. The atomizing chamber 2, the heating chamber 1 and the dry burning chamber 3 are three chambers which are connected together, and the atomizing chamber 2, the heating chamber 1 and the dry burning chamber 3 are arranged from left to right in sequence. The atomizing chamber 2, the heating chamber 1 and the dry burning chamber 3 are separated by partition plates, the top is open, and gas freely flows. The heating chamber 1 is respectively communicated with the upper parts of the atomizing chamber 2 and the dry burning chamber 3, and the respirator 4 is communicated with the atomizing chamber 2 through a gas conveying pipe 32. The lower part of the dry burning chamber 3 is provided with an air inlet hole, and outside air can enter the dry burning chamber 3 through the air inlet hole. The atomizing plate 21 is installed at the bottom of the atomizing chamber 2, in this embodiment, three atomizing plates 21 are installed in the atomizing chamber 2, and the atomizing plates 21 can vibrate at high frequency after being electrified, so as to break up the liquid water molecule structure and generate naturally elegant nano-scale water mist. In order to adjust the atomization rate of the atomization sheet 21, each atomization sheet 21 is connected with a switch, and the work and the closing of the corresponding atomization sheet 21 can be independently controlled by controlling each switch, so that the aim of adjusting the atomization rate of the atomization sheet 21 is fulfilled. The heater 12 is installed at the bottom of the heating chamber 1, and by energizing the heater 12, pure water in the heating chamber 1 is evaporated to generate water vapor. The heating wire 34 is installed at the upper portion of the dry combustion chamber 3, and the temperature of the air in the dry combustion chamber 3 is raised by supplying electricity to the heating wire 34 to generate heat. In this embodiment, the fan 31 is installed in the middle of the dry combustion chamber 3, the fan 31 blows the hot air in the dry combustion chamber 3 and the water vapor in the heating chamber 1 to the atomizing chamber 2, so that the heated air, water vapor and nano-scale water mist are mixed and then enter the respirator 4 through the air pipe 32, the respirator is of a foldable and contractible structure, the respirator is provided with an air suction port through which air is sucked, and of course, the fan 31 can also be installed in the atomizing chamber 2 and the heating chamber 1. The temperature of the nano-scale water mist is improved by mixing the nano-scale water mist, the water vapor and the hot air, and the loss of the nano-scale water mist in the transportation process is reduced, so that the atomization amount of the nano-scale water mist manufacturing equipment is increased.

In order to conveniently and respectively add purified water into the heating chamber 1 and the atomizing chamber 2, the heating chamber 1 and the atomizing chamber 2 are both provided with a water adding port 11 for adding the purified water, when the purified water is lacked in the heating chamber 1 or the atomizing chamber 2, only the cover cap on the water adding port 11 needs to be screwed down to add the purified water, then the cover cap is screwed down, and the nano-scale water mist manufacturing equipment can be continuously used.

In order to reduce the power consumption of the heating wire 34, in the present embodiment, a gas return pipe 33 is provided between the respiratory mask 4 and the dry combustion chamber 3, one end of the gas return pipe 33 is connected to the respiratory mask 4, and the other end is connected to the gas inlet of the dry combustion chamber 3, so that the mixed gas in the respiratory mask 4 is introduced into the dry combustion chamber 3 through the gas return pipe 33. Because the mixed gas in the respirator 4 is higher in temperature and contains a large amount of heat and nanometer water mist, the mixed gas in the respirator 4 is led into the dry burning chamber 3 for cyclic utilization, and the heating wire 34 only needs to consume little electric quantity to heat the gas in the dry burning chamber 3 to the set temperature, so that the electric quantity loss of the heating wire 34 is reduced, and the atomization amount output by the nanometer water mist manufacturing equipment is increased.

The main control board is a central control device and controls the vibration amplitude of the atomizing sheet, the temperatures of the heater and the heating wire and the rotating speed of the fan, and the air supply and suction speed and the concentration of the corresponding solution component in the air are adjusted. The atomizing piece is connected with the main control panel, and the atomizing is indoor to add water, and the atomizing piece vibration produces nanometer water smoke, realizes the adjustment to nanometer water smoke.

Only when formaldehyde detection sensor, PM2.5 detection sensor, temperature and humidity sensor in with the air that detects formaldehyde content, PM2.5 content, temperature, humidity data send to the main control board, compare with the standard value, judge that the testing result is normal, then main control board control atomizing piece, heater strip, fan operate, otherwise judge that the air quality is unqualified, then main control board control atomizing piece, heater strip, fan do not operate.

Example 2

Referring to fig. 1, the present embodiment discloses a method for manufacturing nano water mist by test start, the method includes:

the formaldehyde detection sensor, the PM2.5 detection sensor and the temperature and humidity sensor are used for respectively detecting the formaldehyde content, the PM2.5 content and temperature and humidity data in the air;

the main control board receives the data obtained by detection, judges whether the harmful components in the air exceed the standard or not, and controls each device to work if the harmful components do not exceed the standard;

heating purified water in the heating chamber by using the heater 12 to generate water vapor;

the atomizing sheet 21 is utilized to high-frequency slap the purified water in the atomizing chamber to generate nano-scale water mist;

heating the air in the dry-burning room by using the electric heating wire 34;

the water vapor, the nano-scale water mist and the heated air are mixed by a fan 31 and pushed to a breathing mask;

the mixed gas in the respirator is led into the dry burning chamber 3 through a gas return pipe 33 for cyclic utilization.

After the fan 31 circular telegram was rotated, the air after will dry combustion method room 3 internal heating and the steam propelling movement in the heating chamber 1 to atomizer chamber 2 for steam, nanometer water smoke and the air mixture after the heating, under the promotion of pressure, the gas after the mixture gets into respiratory mask 4 along gas-supply pipe 32.

In the method for producing nano-scale water mist, after the steps are carried out, the mixed gas in the breathing mask 4 is led into the dry burning chamber 3 through the air return pipe 33 for recycling. Because the mixed gas in the respirator 4 is higher in temperature and contains a large amount of heat and nanometer water mist, the air in the respirator 4 is guided into the dry combustion chamber 3 to be reused, and the heating wire 34 only needs to consume little electric quantity to heat the air in the dry combustion chamber 3 to the set temperature, so that the energy loss of the heating wire 34 is reduced, and the atomization amount output by the atomization chamber is increased.

And the whole equipment can be controlled to operate in the environment with qualified air quality, so that the quality of the nano water mist is ensured, and the use experience of a user is improved.

According to the method for manufacturing the nano water mist for test starting, disclosed by the embodiment, the formaldehyde content, the PM2.5 content, the temperature and humidity data in the air are respectively detected through the formaldehyde detection sensor, the PM2.5 detection sensor and the temperature and humidity sensor, whether the standard requirements are met or not is judged, the nano water mist can be started after reaching the standard, and the quality of the nano water mist is ensured. The main control panel controls each electric appliance part, so that centralized and unified control is realized, the atomization process is closer to the actual requirement, and personalized adjustment is performed. The nanoscale water mist is generated through the atomizing sheet, and the noise generated in the working process of the atomizing equipment is reduced. The nanoscale water mist manufacturing equipment generates nanoscale water mist through high-frequency vibration of the atomizing plates, so that the atomizing rate of the atomizing equipment is improved. In addition, the water mist generated by the atomizing plate is nano-scale water mist, so the particle size of the water mist generated by the nano-scale water mist manufacturing equipment is smaller and more uniform compared with the water mist generated by the rotary disc atomizing equipment. The plurality of atomizing sheets are adopted to generate the nano-scale water mist, and the generated nano-scale water mist, the water vapor and the hot air are mixed to improve the temperature of the nano-scale water mist, so that the loss of the nano-scale water mist in the transportation process is reduced, and the atomizing amount of the nano-scale water mist manufacturing equipment is increased.

Although the invention has been described in detail above with reference to a general description and specific examples, it will be apparent to one skilled in the art that modifications or improvements may be made thereto based on the invention. Accordingly, such modifications and improvements are intended to be within the scope of the invention as claimed.

Claims (9)

1. A test-enabled nano-water mist production apparatus, the apparatus comprising: air mass sensor, main control panel, heating chamber, atomizer chamber, dry combustion chamber and respiratory mask, air mass sensor detects the surrounding air quality, and air mass sensor is connected with the main control panel, and air mass sensor's testing result sends main control panel, the heating chamber communicates with atomizer chamber, dry combustion chamber respectively, be provided with the heater in the heating chamber, be provided with the heating wire in the dry combustion chamber, be provided with the atomizing piece in the atomizer chamber, the main control panel is connected with heater, heating wire and atomizing piece respectively, controls the running state of heater, heating wire and atomizing piece, the respiratory mask passes through the gas-supply pipe and is connected with the atomizer chamber, is connected with the dry combustion chamber through the muffler, and the main control panel controls the operation and the stopping of whole device according to the testing result.

2. The test-enabled water mist production apparatus of claim 1, wherein the air quality sensor comprises: formaldehyde detects sensor, PM2.5 and detects sensor, temperature and humidity sensor, formaldehyde detects sensor, PM2.5 and detects sensor, temperature and humidity sensor and all is connected with the main control board, and formaldehyde content, PM2.5 content, temperature, humidity data send to the main control board in the air that will detect.

3. The test-enabled nano water mist manufacturing device as claimed in claim 1, wherein the atomizing chamber, the heating chamber and the dry burning chamber are sequentially arranged in the atomizing housing, the atomizing chamber, the heating chamber and the dry burning chamber are separated by partition plates, the top of the atomizing chamber is open, and gas freely circulates.

4. The test-enabled nano water mist manufacturing device as claimed in claim 1, wherein the inside of the atomizing chamber is provided with an atomizing plate, the atomizing plate is connected with the main control board, water is added into the atomizing chamber, and the atomizing plate vibrates to generate nano-scale water mist.

5. The test-enabled nano water mist manufacturing device as claimed in claim 1, wherein a heater is installed in the heating chamber, the heater is connected with a control mainboard, the control mainboard controls the heater to generate heat, water is injected into the heating chamber, and water vapor is manufactured by heat generated by the heater.

6. The nanometer water mist manufacturing device for test start according to claim 1, wherein a heating wire and a fan are installed in the dry combustion chamber, the heating wire and the fan are both connected with a main control board, the heating wire heats air, the fan blows hot air to promote circulation of gas, and the main control board controls the heating temperature of the heating wire and the wind speed of the fan.

7. The nanometer water mist manufacturing device for the test starting according to claim 1, wherein the top of the atomization chamber is connected with an air pipe, the air pipe is connected to an air inlet of a respirator, the side wall of the dry combustion chamber is connected with an air return pipe, and the air return pipe is connected with an air outlet of a breathing nozzle.

8. The nanometer water mist manufacturing device for test start according to claim 1, wherein the main control board is a central control device, the main control board controls the vibration amplitude of the atomizing plate, the temperature of the heater and the heating wire, and the rotation speed of the fan, adjusts the air supply suction speed and the concentration of the corresponding solution component in the air, and the main control board controls whether the atomizing plate, the heater, the heating wire and the fan operate or not according to the detection result of the air quality sensor.

9. A method for manufacturing nano water mist for test starting is characterized by comprising the following steps:

the formaldehyde detection sensor, the PM2.5 detection sensor and the temperature and humidity sensor are used for respectively detecting the formaldehyde content, the PM2.5 content and temperature and humidity data in the air;

the main control board receives the data obtained by detection, judges whether the harmful components in the air exceed the standard or not, and controls each device to work if the harmful components do not exceed the standard;

heating purified water in the heating chamber by using a heater to generate water vapor;

the atomizing sheet is used for high-frequency slapping purified water in the atomizing chamber to generate nano-scale water mist;

heating the air in the dry burning room by using an electric heating wire;

mixing the water vapor, the nano-scale water mist and the heated air by using a fan and pushing the mixture to a breathing mask;

and introducing the mixed gas in the respirator into a dry burning chamber through a gas return pipe for cyclic utilization.

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