TWI539993B - Atomization Method of Polymeric Polymer Solution - Google Patents

Description

Atomization method of polymer solution

The invention relates to a method for liquid atomization diffusion to achieve indoor fragrance, in particular to a method for atomizing a polymer liquid to achieve a rapid diffusion effect.

Generally, indoor indoors are mostly closed or air-flowing areas, and because people engage in various activities in an indoor environment, they often cause unpleasant odors in the interior, and they cannot disperse themselves for a long time. Therefore, most of the solutions The way is to install various types of aromatic products in the indoor case to improve, so that people have better comfort in the room.

At present, the aromatic device used in the market is nothing more than a heating method to dissipate the aromatic solution to release the aromatic gas. Generally, the heated aromatic device is generally provided with a container for accommodating the fragrance material on the ceramic lamp, and inside the lamp. Set a candle or tungsten bulb to heat the container to allow the fragrance gas to emanate and fill the room.

The other is a product that is passed through a water-heating method. The product is mainly placed in a second container containing the essential oil, placed in a second container containing the water, and then the second container is heated to allow the essential oil to slowly Fly out of its aroma. However, the above two ways of heating to generate aromatic gas are often caused by inadvertent use of the user, which may result in loss of life and property.

The main object of the present invention is to provide a method for atomizing molecules of a high molecular polymer, which ensures that the polymer solution can be rapidly atomized into tiny molecules, and the atomized molecules reach a set diffusion speed, and quickly dissipate into the space outside the container. In turn, it can achieve a fast fragrant effect of the indoor space.

The secondary object of the present invention is to atomize the molecules generated by the solution, and the particle size of the outwardly diffusing atomized molecules can be miniaturized through the filtering means inside the container, thereby enhancing the range of the fragrance of the atomized molecules.

A further object of the present invention is to eliminate the odor, odor, and organic molecules of the cigarette in the air when the polymer polymer solution is atomized into a tiny molecule to emit a fragrant fragrance, and the odor is also eliminated. The dust particles are allowed to settle downward.

In order to achieve the above object, the atomization method of the high molecular polymer solution of the present invention comprises: providing a polymer solution in a container, wherein the polymer solution is made of chitin and its derivatives, polysaccharides and glucosamine. At least one of the components; atomizing the polymer solution to generate atomized molecules inside the container; and filtering and screening the atomized molecules in the container to distinguish the atomized molecules according to particle size In order to act as atomizing molecules and non-acting atomizing molecules, the atomized molecules having a particle size ranging from 0.01 μm to 100 μm are active atomizing molecules, and the atomized molecules having a particle diameter greater than 100 μm are unacting atomizing molecules; Pressing the container to output the above-mentioned activatable atomizing molecules from the inside to the outside to achieve a set amount of fogging, the fogging amount must be 30 ml to 2000 ml per hour; and the above-mentioned unacting atomized molecules are recovered and repeatedly atomized. deal with.

In a preferred embodiment, the atomization process may employ an ultrasonic resonator that provides vibration energy to break up the molecular structure of the polymer solution to form atomized molecules. The above filtering and screening treatment uses a one-way path to allow the atomized molecules to flow, and the atomized molecules having a large volume in the flow process collide with each other to form the above-mentioned unacting atomizing molecules. The pressurized output process is performed by injecting an external gas into the internal cavity of the container or by using a fan to drive the flow of the movable atomizing molecule.

In another preferred embodiment, the atomization treatment may use a heating device to raise the polymer solution to vaporize the polymer to form atomized molecules. The above filtering and screening treatment uses a filter to adsorb the above-mentioned unacting atomizing molecules in the flow process. The above-mentioned pressurized output treatment adopts the above-mentioned container outlet to be designed as a tapered structure, so that the output aperture is smaller than the inner space of the container.

In addition, the above filter screening treatment may also use a container cavity to allow the atomizing molecules to flow, and collide and condense on the surface of the inner cavity of the container to form the above-mentioned unacting atomizing molecules.

The invention has the advantages that the polymer polymer solution acts through the steps of atomization, filtration screening and pressure output, so that when the polymer polymer atomizing molecules are output from the inside of the container, the particle size is 0.01 μm~ 100μm miniaturized molecules, and the atomized molecules reach a set output of 30ml ~ 2000ml per hour, which can quickly dissipate into the space outside the container, thereby achieving the rapid fragrance of the indoor space and enhancing the outward diffusion of the atomizing molecules. The fragrant range, in addition to the fragrance, can also eliminate the smell of cigarettes, eliminate the odor in the air and eliminate the effects of organic molecules in the air, and allow the exposed dust particles to settle down to the ground.

In order to further clarify and understand the structure, the use and the features of the present invention, the preferred embodiment is described in detail with reference to the following drawings:

First, referring to FIG. 1 and FIG. 2, the present invention mainly adds a polymer polymer solution 20 to a container 10 having an atomizing mechanism 112, and then acts through the atomizing mechanism 112 to cause the above-mentioned high. The molecular polymer solution 20 generates a microparticle-size molecular diffusion, wherein the polymer solution 20 is composed of at least one of chitin and a derivative thereof, a polysaccharide, and glucosamine.

As shown in the figure, the container 10 of the present invention is mainly composed of a body 11 and a top cover 12, wherein the seat body 11 has an opening-up liquid filling space 111, and a mist is installed in the liquid containing space 111. The top cover 12 has an output hole 121 communicating with the liquid containing space 111, and the inner surface is provided with a plurality of fixing members 122 for surface mounting of the seat body 11.

Therefore, when the atomization treatment is to be performed, the top cover 12 must be separated from the upper portion of the seat body 11 to expose the liquid containing space 111, and then the polymer solution 20 is added to the liquid containing space 111. The polymer solution 20 is brought into contact with the atomizing mechanism 112.

Referring to FIG. 2 again, in a possible embodiment, the atomization mechanism 112 is configured as an ultrasonic resonator that provides vibration energy, and the molecular structure of the polymer solution 20 can be broken up to form atomization. Molecule 21. When the atomization mechanism 112 acts, the polymer solution 20 forms an atomization region at a position above the ultrasonic resonator, and atomization molecules 21 of different particle sizes are generated from the atomization region, and The atomized molecules 21 are filled in the liquid containing space 111 of the container 10.

However, the ultrasonic resonator is only for convenience of illustration, that is, the atomization mechanism 112 can also be configured as a heating device for providing thermal energy, and the high molecular polymer solution 20 is vaporized to directly form a mist capable of rapidly diffusing. Molecule 21.

As shown in FIG. 3, the inside of the top cover 12 of the present invention is provided with a blocking piece 123 at a position below the output hole 121, and the blocking piece 123 cooperates with the inner cavity of the top cover 12 to form a passage 124 for filtering. The above-mentioned blocking piece 123 mainly prevents the atomizing molecules 21 from directly spreading upward and rushing out of the inside of the container 10. The above-mentioned passage 124 is mainly used for filtering and screening the above-mentioned atomizing molecules 21.

Wherein, a part of the atomized molecules 21 having a larger particle diameter collide with each other to form water droplets during the movement of the liquid containing space 111 and the passage 124, and start to settle due to an increase in volume and weight, and the other portion has a larger particle diameter. The atomizing molecule 21 will contact the inner peripheral wall of the above-mentioned seat body 11 to be condensed and adsorbed on the surface, and after the water droplet is formed, it also starts to move downward along the wall surface due to the increase in volume and weight. Further, the atomized molecules 21 having a small particle diameter are gradually shifted toward the output hole 121 in accordance with the flow direction of the liquid containing space 111 and the passage 124.

According to the foregoing description, the atomization molecule 21 is divided into an atomizable molecule that can be outputted outwardly and an unactuated atomized molecule that is coagulated and settled according to the particle size. In a preferred embodiment, the atomization is performed. The particle size of the molecule 21 is between 0.01 μm and 100 μm, which is an atomizable molecule, and the particle size of the atomized molecule 21 is greater than 100 μm.

Similarly, the foregoing filtering method is only used for convenience of description, that is, the container 10 can directly be directly disposed below the output hole 121 with a filter screen (not shown), and the filter screen directly blocks the excessive particle size. The atomizing molecule 21 allows the atomizing molecule 21 having a small particle size to directly diffuse outward through the screen.

Referring to FIG. 4, a fan 13 for forming a pressurized output means is further disposed inside the base of the present invention, and the fan 13 has a blowing path 131 communicating with the liquid containing space 111, and continuously sucks air toward the outside. Internally transporting gas.

In addition, the other side of the channel 124 relative to the output aperture 121 is defined as a range of the opening area larger than the area of the output aperture 121, so that the channel 124 forms a tapered structure. When the molecules flow into the interior of the channel 124, the diffusion velocity ejected by the output aperture 121 can be additionally increased depending on the design of the structure.

As shown in the figure, the gas will move downward from the periphery of the liquid containing space 111 according to the air supply path, and will be reversely moved upward after contacting the surface of the polymer solution 20, and then according to the limitation of the shape of the container 10, along the The periphery of the wall surface of the container 10 is moved upward to the inside of the passage 124, and finally discharged from the output hole 121 toward the outside, so that the overall output fogging amount must reach 30 ml to 2000 ml per hour, so that the polymer can be Rapidly spread to the entire interior space.

In another possible embodiment, the pressure output means may be a gas delivery device (not shown), and an external gas is injected into the interior of the container 10 to mix the external gas with the atomizing molecule 21, and It is sprayed outward by the output hole 121 of the above container 10.

Referring to FIG. 5, it can be seen from the foregoing description that the atomization method of the present invention can be summarized as follows: Step A: A polymer solution is provided inside a container. Step B: atomizing the above polymer solution to generate atomized molecules inside the container. Step C: filtering and screening the atomized molecules in the inside of the container, so that the atomized molecules are divided into activatable atomizing molecules and non-acting atomizing molecules according to particle size. Step D: The pressure treatment causes the container to output the above-mentioned activatable atomizing molecules from the inside to the outside to achieve a set amount of fogging. Step E: The above-mentioned unacting atomized molecule recovery is repeatedly subjected to atomization treatment.

The particle size of the polymer after atomization of the polymer solution is atomized, and the atomized molecules reach a set diffusion speed, and quickly dissipate into the space outside the container, thereby achieving a fast fragrant effect in a wide range of indoor spaces.

Further, when the atomized polymer solution is fragrant in the air, the odor molecules of the cigarette in the exposed air can be eliminated, and the odor molecules in the exposed air can be eliminated. Eliminates the presence of organic molecules (such as aldehyde molecules) in the exposed air and the effect of allowing the exposed dust particles to settle down to the surface.

The above-mentioned embodiments are merely intended to be illustrative of the present invention and are not intended to limit the scope of the invention, and the various modifications and modifications made by those skilled in the art in accordance with the scope of the invention and the description of the invention are still It is included in the scope of the following patent application.

10---Container 11---Body 111---Liquid space 112---Atomizing mechanism 12---Top cover 121---Output hole 122---Fixed part 123---Block 124 ---Channel 13---Fan 131---Air supply path 20---High molecular polymer solution 21---Atomization molecule

1 is a schematic view showing a solution of a polymer electrolyte solution added to a container of the present invention; FIG. 2 is a schematic view showing a solution of a resonance atomization polymer polymer of a container according to the present invention; Schematic diagram of channel filtration; Figure 4 is a schematic diagram of the pressurized output of the present invention capable of rapidly dispersing atomized molecules; and Figure 5 is a flow chart of the method for atomizing a high molecular polymer solution of the present invention.

no.

Claims (12)

A method for atomizing a polymer solution comprises the steps of: (A) providing a polymer solution in a container; (B) atomizing the polymer solution to produce the inside of the container (A) filtering and screening the atomized molecules in the inside of the container, so that the atomized molecules are classified into activatable atomizing molecules and non-acting atomizing molecules according to particle size; (D) pressure treatment The container is caused to output the above-mentioned activatable atomizing molecules from the inside to the outside to achieve a set amount of fogging. The method for atomizing a high molecular polymer solution according to claim 1, wherein the method further comprises the step (E): repeating the atomization treatment by recovering the unactual atomized molecules. The method for atomizing a polymer solution according to the first aspect of the invention, wherein the polymer solution is composed of at least one of chitin and a derivative thereof, a polysaccharide and glucosamine. According to the atomization method of the high molecular polymer solution according to the first aspect of the patent application, wherein the atomization molecular size of the atomized molecule is between 0.01 μm and 100 μm, and the atomized molecular particle size is greater than 100 μm. No atomizing molecules are acted upon. According to the atomization method of the high molecular polymer solution according to Item 1, the above-mentioned fogging amount is 30 ml to 2000 ml per hour. According to the atomization method of the high molecular polymer solution according to claim 1, wherein the atomization treatment may use an ultrasonic resonator that provides vibration energy to break up the molecular structure of the polymer solution to form atomization. molecule. The atomization method of the high molecular polymer solution according to the first aspect of the patent application, wherein the filtering and screening treatment uses a one-way path to allow the atomized molecules to flow, and the atomized molecules having a large volume in the flow process collide with each other. Settling forms the above-mentioned unacting atomized molecules. According to the atomization method of the high molecular polymer solution according to claim 1, wherein the filtering and screening treatment uses a container cavity to allow the atomized molecules to flow, and collides with the atomized molecules having a large volume in the flow process. The surface of the inner cavity of the container forms the above-mentioned non-acting atomizing molecules. The method for atomizing a high molecular polymer solution according to claim 1, wherein the filtering and screening treatment uses a filter to adsorb the above-mentioned non-acting atomizing molecules during the flow. The atomization method of the high molecular polymer solution according to the first aspect of the invention, wherein the pressurized output treatment uses a fan to blow the movable atomizing molecules. The atomization method of the high molecular polymer solution according to the first aspect of the invention, wherein the pressurized output treatment is performed by injecting an external gas into an internal cavity of the container. The atomization method of the high molecular polymer solution according to the first aspect of the invention, wherein the pressurizing output treatment designes the container outlet as a tapered structure.