KR20040087349A - CIGARETTES ADDED NANO-Ag-PARTICLES AND MANUFACTURING METHOD THEREOF - Google Patents

Abstract

PURPOSE: A cigarette with nano silver particles and a manufacturing method thereof are provided to prevent deterioration of adsorbing a harmful material and detoxication. CONSTITUTION: The manufacturing method comprises the steps of: (S04) preparing a cigarette by (S02) processing and (S03) cutting a leaf cigarette and rolling with a cigarette paper; (S20) preparing a filter; (S05) bonding the cigarette and the filter; and (S10) adding nano silver particles in the step (S20), (S04) or (S05). The cigarette with nano silver particles comprises a cigarette formed by rolling the processed leaf cigarette with a cigarette paper; a filter bonded to one side of the cigarette and filtering a harmful material inhaled; and a filter membrane with nano silver particles which is located between the cigarette and the filter or inserted into the filter and adsorbs or removes the harmful material.

Description

Tobacco with nano silver particles added and its manufacturing method {CIGARETTES ADDED NANO-Ag-PARTICLES AND MANUFACTURING METHOD THEREOF}

The present invention relates to a cigarette to which nano silver particles are added, and a method of manufacturing the same. Particularly, nano silver particles are added to the tobacco or filter of the cigarette to remove the harmful components of the cigarette. And to a method for producing the same.

Generally, tobacco is processed from leaf tobacco as raw material.

Such cigarettes are mostly for smoking, and are classified into cigarettes, cigars, and squares according to their shapes.

Cigarettes now make up the majority of the world, and cigarettes are commonly referred to as cigarettes.

Such tobacco is prepared by mixing various tobacco leaves as raw materials, processing the mixed raw materials, cutting the raw materials into appropriate sizes, and then attaching a filter.

The mixing of the leaf tobacco is a process for producing a more unique tobacco using the unique aroma, taste, color, etc. of the various tobacco leaves, through which gives the characteristic characteristics of the various tobacco to have a unique taste. That is, the basic taste and aroma of the product are determined through this mixing.

The processing of raw materials enhances the marketability through processes such as fermentation, heating, fragrance, and removal of defective parts, and softens the leaves through a humidification or heating process. In the general public, the leaves are roasted for this purpose.

After the above process is cut to the appropriate size and transported to the cigarette maker.

In a cigarette maker, the cut leaf tobacco mixture is rolled into cigarette paper to produce a membrane-free cigarette.

Such a membrane cigarette is combined with the filter in the filter attachment to make a filter cigarette, these individual filter cigarettes are packaged to finally complete the product.

Tobacco produced by the method described above is a favorite of many because of its unique fragrance and ingredients.

However, since such cigarettes contain a large amount of harmful substances in the human body, excessive smoking can cause serious problems for the human body. Therefore, regulations to prohibit smoking in public places have been established, and the level of the regulation is gradually increasing. .

There are more than hundreds of harmful components in the cigarettes, especially in tar, as many as 15 kinds of carcinogens are currently known.

Since these harmful substances are included in the smoke of the smoke and spread in the air, it can seriously affect not only those who smoke directly but also those around them.

Knowing the harmfulness of such cigarettes, it is difficult to quit smoking due to the addictive effects of nicotine, and most users smoke cigarettes without any measures.

Global tobacco annual consumption is estimated at more than 5 trillion, and thousands of people are dying or being treated for various diseases.

It is an object of the present invention to provide a tobacco and a method for manufacturing the same, wherein nano silver particles are added to detoxify and detoxify harmful substances of tobacco.

In addition, another object of the present invention is to prevent the nano-sized silver particles added to the cigarette to be oxidized in the air, the tobacco and nano-particles added to the nano silver particles that can prevent the deterioration of the adsorption and detoxification of harmful substances To provide a manufacturing method.

The present invention for achieving the above object is configured to mix the nano-sized silver particles in the leaf tobacco material, to include the silver particles in the filter, or to add the silver particles between the membrane scouring and the filter and / or inside the filter. Has its features.

In addition, the present invention is characterized in that the surface of the nano-sized silver particles are configured to be coated with silicon oxide.

1 is a flow chart of the manufacturing process of tobacco nano silver particles added according to the present invention.

FIG. 2 is a flowchart of a manufacturing process of nano-sized silver particles to be added in FIG. 1. FIG.

Figure 3 is a perspective view of one embodiment of the tobacco nano nanoparticles added according to the present invention.

Figure 4 is another embodiment separated perspective view of the tobacco nano silver particles added in accordance with the present invention.

5 to 8 are micrographs of the results of the antimicrobial activity of silver.

* Description of the symbols for the main parts of the drawings *

10 filter 11: first filter part

12. Second filter portion 13: Filter membrane to which nano silver particles are added

20: Membrane

When described in detail with reference to the accompanying drawings a preferred embodiment of the present invention configured as described above are as follows.

1 is a manufacturing process flow chart of the present invention nano silver particles added tobacco, mixing step of mixing the leaf tobacco as shown therein (S01); A raw material processing step (S02) of processing the mixed raw material; Raw material cutting step (S03) for finely cutting the processed mixed leaf tobacco; A membrane scouring manufacturing step (S04) of manufacturing a membrane scouring using the cut raw material using a scouring machine; A combining step (S05) of manufacturing a cigarette by combining the filter prepared through a separate filter manufacturing step (S20) with the above-described membranes; In the cigarette manufacturing method comprising a packaging step (S06) for packaging the cigarette, nano silver particles are added to the filter produced in the filter manufacturing step (S20), or membrane scouring in the membrane scouring manufacturing step (S04) The nano silver particle addition step (S10) is added to the inside, or added between the membrane scouring and the filter in the bonding step (S05) of combining the membrane scouring and the filter.

FIG. 2 is a flowchart illustrating a process of manufacturing the nano silver particles used in the nano silver particle addition step (S10). As shown therein, a silver solution, distilled water, and β-Alanine are mixed to form a mixed solution (S11). )Wow; Stirring methanol, ethoxy ethanol and diethylene glycol in the mixed solution (S12); Stirring the silicon compound or the silicon compound derivative in the mixed solution (S13); Checking whether the hydrolysis of the silicon compound or the silicon compound derivative is completed and returning to step S13 if it is not completed (S14); When the hydrolysis is completed, adding triethanolamine and ammonia water to form a complex compound (S15); Reducing silver particles by adding hydrazine monohydrate (H ₂ NNH ₂ · H ₂ O, hydrazine monohydrate) to the complexed solution (S16); Washing the reduced silver particles (S18); Freeze-drying the silver particles to obtain nano-sized silver particles coated with silicon oxide (S18) to obtain nano-sized silver particles coated with silicon oxide used in the nano silver particle addition step (S10). Done.

Hereinafter, a method of obtaining nano-sized particles coated on the surface of the silicon oxide and specific examples of adding the obtained nano-sized silver particles in a tobacco manufacturing process will be described in more detail.

First, a method of obtaining nano-sized silver particles coated with silicon oxide will be described in more detail.

In step S11, 20 g (1.22 m) of β-Alanine (alanine) is added to a mixed solution of 100 ml (0.1 m) of Ag solution and 100 ml of distilled water, which is fixed at 1 m.

Next, in step S12, 400 ml of methanol, 200 ml of ethoxy ethanol, and 200 ml of diethylin glycol are added to the solution, followed by stirring.

Then, in step S13, after completely stirring the solution, the silicon compound or silicon compound derivative is added and stirred again to hydrolyze the silicon compound or silicon compound derivative.

At this time, the silicon compound or silicon compound derivative is silicon combined with oxygen and hydrogen.

Next, in step S14, it is checked whether the silicon compound or the silicon compound derivative is completely hydrolyzed.

At this time, if the hydrolysis is not completely, since the silicon compound or the silicon compound derivative acts as a impurities, if the hydrolysis is not complete, the stirring process of step S13 is repeated.

Next, in step S15, 10 g of triethanolamine is added to the hydrolyzed state, and then 100 g of ammonia is added to form a complex compound.

Next, in step S16, 100 ml (2.0 m) of hydrazine monohydrate (H ₂ NNH ₂ · H ₂ O, hydrazine monohydrate) is added to the solution to reduce the silver particles.

Then, in step S17, the reduced silver particles are filtered and washed six times with 300 ml of distilled water, three times with 300 ml of a solvent in which ethanol and distilled water are mixed 1: 1, and then with 300 ml of ethanol. To remove impurities completely.

Next, in step S18, the wet silver particles obtained as described above are lyophilized at a temperature range of −70 to 50 ° C. to obtain pure monodisperse silver nano-fine particles.

The monodisperse silver nano-fine particles obtained as described above have an even particle size distribution, high electromagnetic properties, and easy secondary dispersion.

The nano-sized silver particles thus obtained are coated with silicon oxide so that their surface is oxidized even under air or ultraviolet light, or their properties are not changed.

The nano-sized silver particles produced by the above method may be added to the cigarette in the membrane scouring step (S04), the filter manufacturing step (S20), or the coupling step (S05) of combining the membrane scouring and the filter.

The method for adding nano-sized silver particles in the membrane scouring manufacturing step (S04) is to cut the processed leaf tobacco, and then evenly mix the nano-sized silver particles to prepare the membrane scouring using the processed and cut leaf tobacco. .

Membrane cistern prepared as described above is combined with a filter manufactured through a separate process to complete the cigarette.

In addition, the method of adding nano-sized silver particles in the filter manufacturing step (S20) may allow the silver particles to be evenly distributed in the filter itself, and insert a filter membrane including nano-sized silver particles in the middle of the filter. It may be.

3 is an exploded perspective view of the filter 10 according to the present invention. As shown in the drawing, the filter 10 includes a first filter part 11 which contacts the smoker's mouth and a second filter part 12 which contacts the membrane scouring. ) And the filter membrane 13 to which nano silver particles are added between the first filter unit 11 and the second filter unit 12.

That is, by providing the filter membrane 13 to which the nano silver particles are perpendicular to the direction in which the user inhales the tobacco smoke in the middle of the filter 10, the toxicity of the harmful substances contained in the tobacco smoke is reduced. .

At this time, the filter membrane 13 contains nano silver particles coated with silicon oxide on the surface, which prevents the silver particles from oxidizing, and even if the cigarette is left in the air for a long time, the properties of the silver particles do not change. The detoxification action can occur smoothly.

4 is an exploded perspective view of the tobacco when silver particles are added to the cigarette in the bonding step, and as shown in FIG. 4, silicon oxide is deposited between the membrane scouring 20 and the filter 10 with or without the silver particles. The membrane membrane 20 and the filter 10 are combined by inserting the filter membrane 13 including nano silver particles coated on the surface.

The filter membrane 13 may be a thin membrane in which nano silver particles coated with silicon oxide are injected, or a double membrane bag containing the nano silver particles coated with silicon oxide may be used. Any configuration can be used as long as it can distribute nano silver particles evenly with respect to the suction direction.

The deodorizing power of the nano silver particles was tested by the Korea Yarn Textile Testing Institute (Accession No. 41-41-03-04277) to prove the effect.

As the test gas, ammonia gas contained in cigarette smoke was used, and 8 μl of the ammonia gas was injected into a 3 liter sealed container, and the deodorization rates were measured after 5, 15, 30, and 60 minutes.

The deodorization rate increased to 5.7% after 5 minutes, 8.3% after 15 minutes, 10.0% after 30 minutes, and 12.5% after 60 minutes.

Thus, harmful components of tobacco are adsorbed and removed by the nano silver particles added in the present invention.

The effect obtained by adding nano silver particles to tobacco can not only adsorb harmful components such as ammonia gas, but also reduce the number of bacteria in the mouth.

5 to 8 are microscopic images of the test results of the antimicrobial activity of the sample containing or not containing the nano-silver particles used in the present invention, Figures 5 and 7 contain silver particles for strain 1 and strain 2, respectively 6 and 8 are micrographs of the test results when the nano silver particles were included for the strain 1 and the strain 2, respectively.

The strain 1 is Staphylococcus aureus ATCC 6538, strain 2 is Escherichia coli ATCC 25922.

The antimicrobial activity was measured according to the film adhesion method ((FC-TM-20) -2001), and the conditions of the test were after the incubation of the test bacteria solution at a temperature of 35 ± 1 ° C. at RH90% for 24 hours, and then the bacterial count. Measured. The surface area of each sample used what was 25 cm <2>.

In addition, Stomacher ^® 400 POLY-BAG was used as the standard coating film, and the above test was conducted by the Korea Yarn Textile Testing Institute (Accession No. 41-41-03-04277).

5 and 6, the initial bacterial count was 1.3 × 10 ⁵ bacteria / ml, and the increase or decrease of the bacterial count was examined after 24 hours.

As a result, the number of bacteria in the sample of FIG. 3 without the nanosilver particles applied in the present invention increased about 46 times to 6.0 × 10 ⁶ bacteria / ml, and the sample of FIG. 4 containing the nanosilver particles contained 10 bacteria. It can be seen that most bacteria were reduced to a few ml.

In addition, as shown in Figure 7 and 8 was also tested for strain 2 under the same conditions as the above test, the initial bacterial count at this time is 1.6 × 10⁵The bacterial count of the sample of FIG. 7 containing no nano silver particles was found to be 7.7 × 10.⁶Bacterial count was increased to / ml, the number of bacteria in the sample of Figure 8 containing nano silver particles 10 It can be seen that the bacteria count / ml or less.

As a result of the above experiment, when using nano silver particles, it is possible to remove more than 99.9% bacteria.

The present invention has been shown and described with reference to certain preferred embodiments, but the present invention is not limited to the above-described embodiments and has ordinary skill in the art to which the present invention pertains without departing from the concept of the present invention. Various changes and modifications are possible by the user.

As described above, the present invention has the effect of adsorbing and detoxifying harmful substances by adding nano-sized silver particles coated with silicon oxide to the tobacco.

In addition, the present invention forms a silicon oxide coating film on the surface of the silver particles added to the cigarette, and even when the cigarette is left in the air to prevent the silver particles from being oxidized, such as to change the properties of the harmful substances detoxification is reduced There is an effect to prevent it.

Claims (5)

Membrane citrus formed by rolling the processed leaf tobacco with a citrus paper; In the cigarette composed of a filter for filtering the harmful substances inhaled coupled to one side of the membrane scouring, The nano-silver particles added tobacco, characterized in that it further comprises a filter membrane which is located between the membrane scouring and the filter, or is inserted into the filter to the nano-sized silver particles to adsorb and remove the harmful substances. According to claim 1, wherein the membrane scouring or / and filter is nano silver particles added cigarettes, characterized in that the addition of nano-sized silver particles. The tobacco of claim 1 or 2, wherein the nano-sized silver particles are coated with silicon oxide. A membrane cigarette manufacturing step of processing and cutting the leaf tobacco, and rolling it into a roll of paper to manufacture membranes; A filter manufacturing step of manufacturing a filter; In the cigarette manufacturing method comprising a coupling step of coupling the membrane scouring and filters, The membrane manufacturing step, the filter manufacturing step or / and the bonding step of the nano silver particles added tobacco manufacturing method comprising the step of adding a nano-size silver particles. 5. The method of claim 4, wherein the nano-sized silver particles are coated with silicon oxide on the surface thereof.