CN111109302A - Antimicrobial aerosol and toxicant exposure spray suspended particle spray and preparation method thereof - Google Patents

Abstract

The invention provides an antimicrobial aerosol and toxicant exposure spray suspended particle, which utilizes supercritical CO₂The solid suspension particle spray is obtained by introducing a composite nano-additive flow aid into the phillylphenol, eucalyptus globulus and sodium alginate disinfection main body suspension particles and rapidly expanding the mixture, and the invention has the beneficial effects that: the antimicrobial aerosol and toxicant-exposure spray suspension particle prepared by the preparation process and the method are applied to human bodiesThe product has no toxicity (the traditional Chinese medicine type disinfection material which is already produced in quantity is purchased and used as the main body of the disinfection suspension particles), has the effects of preventing viral upper respiratory tract infection, new crown pneumonia and hand-foot-and-mouth disease, and blocking harmful substances in the air from being absorbed through respiratory tract mucous membranes and lungs, adopts a manual pump spray bottle, and has the advantages of simple filling, low cost and convenient use.

Description

Antimicrobial aerosol and toxicant exposure spray suspended particle spray and preparation method thereof

[ technical field ] A method for producing a semiconductor device

The invention relates to the technical field of antimicrobial compounds or compositions thereof, in particular to an antimicrobial aerosol and toxicant-exposure spray suspended particles and a preparation method thereof.

Air contains a large amount of nitrogen oxides, aerosols and respirable particles, and a large number of harmful particles spread in the air stream and human stream, which may lead to further proliferation of a large number of viruses, bacteria and fungi in the attached particles. New coronary pneumonia, influenza and hand-foot-mouth disease are mostly affected through respiratory tract. The spread of the aerosol and the contamination droplets of the microorganisms in the atmosphere is very harmful and difficult to control, and the disease of some severe patients develops quickly, even the virus can spread in a contact way. The existing mask cannot be used in the processes of eating and sleeping and has antiviral and bactericidal effects in the air.

[ summary of the invention ]

The invention aims to provide a novel antimicrobial aerosol and toxicant spray suspension particle spray and a preparation method thereof, wherein the existing disinfectant mainly disinfects the surface of a general object by a liquid method, and aims at the defects of insufficient technologies of microbial aerosol and toxicant spray due to the problem of liquid sedimentation.

The invention is realized by the following technical scheme:

an antimicrobial aerosol and toxicant-exposure spray suspension granule is prepared by introducing composite nanometer additive glidant into supercritical CO2 and phillyrin, eucalyptus globulus and sodium alginate to sterilize main suspension granules, and rapidly expanding to obtain solid suspension spray.

Further, the antimicrobial aerosol and the toxicant-exposure spray suspended particle are composed of the following components in percentage by weight:

and (3) forsythol: 6 percent of

Eucalyptus globulus Labill: 3 percent of

Sodium alginate: 0.3 percent of

The composite nano additive comprises: and (4) the balance.

Furthermore, the particle size of the suspended particles is 10-15 μm, the particle size distribution is uniform, and the geometric structure is uniform.

Further, the particle size of the composite nano additive is less than 1 μm.

Further, the composite nano additive is a montmorillonite inorganic material.

A method for preparing an antimicrobial aerosol and toxicant spray suspension particle spray, comprising the steps of:

s1, firstly, preparing the composite nano additive with the particle size less than 1 mu m for later use;

s2, mixing phillyrin, eucalyptus globulus and sodium alginate uniformly;

s3, mixing the materials in the step S2 uniformly, introducing the mixture into the composite nano additive by an air classification ACM grinding, cold crushing, numerical control feeding speed fine crushing, C-grade sieving, quick expansion, wind sieving separation and deposition method to prepare suspension particle spray;

s4, filtering the suspended particle spray prepared in the step S3 through a special bag;

s5, filtering the special bag in the step S4, and then quantitatively filling the special bag into a spray bottle through canning equipment to form suspended particle spray;

and S6, finally, canning the suspended particle spray in a spray bottle to obtain a finished product.

Further, the composite nano additive in step S1 is prepared by activating and slowly releasing a biological material system with supercritical CO2 and Bi particles, heating at a temperature, accelerating centrifugal atomization drying, and removing the nano material attached to the surface of the inorganic particles.

The invention has the beneficial effects that: the antimicrobial aerosol and the contamination spray suspension particle spray prepared by the preparation process and the method are nontoxic to human bodies (the purchased and used traditional Chinese medicine type disinfection materials in mass production are taken as main bodies of the disinfection suspension particles), have the effects of preventing viral upper respiratory tract infection, new crown pneumonia and hand-foot-and-mouth disease, and blocking harmful substances in the air from being absorbed through respiratory tract mucous membranes and lungs, and are simple to fill, low in cost and convenient to use by adopting a manual pump spray bottle.

[ detailed description ] embodiments

The invention is further described below with reference to specific embodiments:

example 1:

an antimicrobial aerosol and toxicant-exposure spray suspension, using supercritical CO₂And introducing a composite nano-additive flow aid into the phillylphenol, eucalyptus globulus and sodium alginate mixed sterilization main body suspension particles, and rapidly expanding to obtain the solid suspension particle spray.

Further, the antimicrobial aerosol and the toxicant-exposure spray suspended particle are composed of the following components in percentage by weight:

and (3) forsythol: 6 percent of

Eucalyptus globulus Labill: 3 percent of

Sodium alginate: 0.3 percent of

The composite nano additive comprises: the balance;

further, the forsythia suspensa powder is obtained by extracting dried fruits of forsythiasusapona (Thunb.) Vakl, a plant of the family of trifoliaceae, (purchased from a Chinese medicine factory in Jiangxi);

eucalyptus globulus Labill, which is extracted from dried leaves of Eucalyptus globulus Labill, a plant of Myrtaceae (purchased from Chinese medicine factories in Jiangxi province);

sodium alginate is a natural polymer compound, and is extracted from algae organisms (purchased from Shenzhen Chinese medicinal institute);

raw materials for composite nano-additive manufacturing, (partially purchased from canada and chinese particle technology collaboration).

Furthermore, the suspended particles have the particle size of 10 microns, are uniform in particle size distribution and uniform in geometric structure, and are characterized in that the interaction force among the particles is far higher than the gravity of the particles, and the suspended particles are extremely easy to adhere to microbial aerosol and toxicant droplets in air to form agglomeration.

In a room, the sterilizing suspended particles with the particle size of 10 mu m are optimally distributed and concentrated within 60 seconds, trace sterilizing suspended particles can still be detected within 48 hours, and an FA-1 impact type air microorganism sampler is adopted; the sampling flow is 30L/min, a point is arranged at the center of the room and 1m away from the ground for sampling, the sampling is carried out when the disinfection action time is 0min and 60min, the sampling time of the control group sampler is 5s and 5s respectively, the sampling time of the experimental group sampler is 5s and 1min respectively, the number of viable bacteria stored at different time is measured after sampling, and the killing rate of 3 times of experiments is more than 98.3 percent.

Further, the particle size of the composite nano additive is less than 1 μm.

Further, the composite nano additive is a montmorillonite inorganic material.

A method for preparing an antimicrobial aerosol and toxicant spray suspension particle spray, comprising the steps of:

s1, firstly, preparing the composite nano additive with the particle size less than 1 mu m for later use;

s2, mixing phillyrin, eucalyptus globulus and sodium alginate uniformly;

s3, mixing the materials in the step S2 uniformly, introducing the mixture into the composite nano additive by an air classification ACM grinding, cold crushing, numerical control feeding speed fine crushing, C-grade sieving, quick expansion, wind sieving separation and deposition method to prepare suspension particle spray;

s4, filtering the suspended particle spray prepared in the step S3 through a special bag;

s5, filtering the special bag in the step S4, and then quantitatively filling the special bag into a spray bottle through canning equipment to form suspended particle spray;

and S6, finally, canning the suspended particle spray in a spray bottle to obtain a finished product.

Further, the composite nano additive in step S1 is prepared by activating and slowly releasing a biological material system with supercritical CO2 and Bi particles, heating at a temperature, accelerating centrifugal atomization drying, and removing the nano material attached to the surface of the inorganic particles.

Example 2

Preferably, when the particle size of the suspended particles is 13 microns, the particle size distribution is uniform, the geometric structure is uniform, and the suspended particle disinfection suspended particles are sprayed in the air, can float away from the original area of the suspended particle disinfection suspended particles due to wind direction and wind speed, and can be diffused to the position 1km downwind to keep the viscosity of the suspended particle disinfection suspended particles;

in a room, the distribution concentration of the disinfection suspended particles with the particle size of 15 mu m is optimal within 60 seconds, and trace disinfection suspended particles can still be detected within 48 hours, and an FA-1 impact type air microorganism sampler is adopted; the sampling flow is 30L/min, a point is arranged at the center of the room and 1.5m away from the ground for sampling, the sampling is carried out when the disinfection action time is 0min and 60min, the sampling time of the control group sampler is 5s and 5s respectively, the sampling time of the experimental group sampler is 5s and 1min respectively, the number of viable bacteria stored at different time is measured after sampling, and the killing rate of 3 times of experiments is more than 98.6 percent.

Example 3

In a room, when the distribution concentration of the disinfection suspended particles with the particle size of 15 mu m is optimal within 60 seconds, trace disinfection suspended particles can still be detected within 48 hours, and an FA-1 impact type air microorganism sampler is adopted; the sampling flow is 50L/min, a point is arranged at the center of the room and 4.5m away from the ground for sampling, the sampling is carried out when the disinfection action time is 0min and 60min, the sampling time of the control group sampler is 5s and 5s respectively, the sampling time of the experimental group sampler is 5s and 1min respectively, the number of viable bacteria stored at different time is measured after sampling, and the killing rate of 3 times of experiments is more than 98.8 percent.

In the above-mentioned examples, in order to verify whether the antimicrobial aerosol and the contamination spray suspension particle spray of the present invention achieve the expected invention effect, the antiviral and antibacterial test was performed on the harmful microorganism aerosol, virus and bacteria resistant spray powder of the present invention, and the results of the antiviral and antibacterial rates were as follows:

note that, the test of the disinfection and bacteriostasis rate is only performed on common viruses and germs, and the invention aims at the new coronavirus, and the pneumonia virus sample is not obtained. According to the data and the effect of the above embodiments, all can kill the new coronavirus in the air.

Appropriate changes and modifications to the embodiments described above will become apparent to those skilled in the art from the disclosure and teachings of the foregoing description. Therefore, the present invention is not limited to the specific embodiments disclosed and described above, and some modifications and variations of the present invention should fall within the scope of the claims of the present invention. Furthermore, although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.

Claims (7)

1. An antimicrobial aerosol and toxicant-exposure spray of suspended particles, characterized in that: by using supercritical CO₂And introducing a composite nano-additive flow aid into the phillylphenol, eucalyptus globulus and sodium alginate mixed sterilization main body suspension particles, and rapidly expanding to obtain the solid suspension particle spray.

2. The antimicrobial aerosol and toxicant spray aerosol suspension of claim 1, wherein: the composite material comprises the following components in percentage by weight:

and (3) forsythol: 6 percent of

Eucalyptus globulus Labill: 3 percent of

Sodium alginate: 0.3 percent of

The composite nano additive comprises: and (4) the balance.

3. The antimicrobial aerosol and toxicant spray aerosol suspension of claim 1, wherein: the particle size of the suspended particles is 10-15 mu m, the particle size distribution is uniform, and the geometric structure is uniform.

4. The antimicrobial aerosol and toxicant spray aerosol suspension of claim 2, wherein: the particle size of the composite nano additive is less than 1 mu m.

5. The antimicrobial aerosol and toxicant spray aerosol suspension of claim 2, wherein: the composite nano additive is a montmorillonite inorganic material.

6. The method of making an antimicrobial aerosol and toxicant spray suspension of particles of claim 1, comprising the steps of:

s1, firstly, preparing the composite nano additive with the particle size less than 1 mu m for later use;

s2, mixing phillyrin, eucalyptus globulus and sodium alginate uniformly;

s3, mixing the materials in the step S2 uniformly, introducing the mixture into the composite nano additive by an air classification ACM grinding, cold crushing, numerical control feeding speed fine crushing, C-grade sieving, quick expansion, wind sieving separation and deposition method to prepare suspension particle spray;

s4, filtering the suspended particle spray prepared in the step S3 through a special bag;

s5, filtering the special bag in the step S4, and then quantitatively filling the special bag into a spray bottle through canning equipment to form suspended particle spray;

and S6, finally, canning the suspended particle spray in a spray bottle to obtain a finished product.

7. The method of making an antimicrobial aerosol and toxicant spray suspension of particles of claim 6, wherein: the composite nano additive in the step S1 is prepared by using supercritical CO₂The Bi particles are utilized to activate and slowly release a biological material system, then the biological material system is heated at a temperature, and then the nano material with the formula attached to the surfaces of the inorganic particles is removed by accelerated centrifugal atomization drying, so that the composite nano additive is obtained.