KR0118114B1 - Method & products of adding kindney stone in the process for cooling beverage - Google Patents

Abstract

The invention provides a soft drink having the inherent efficacy of nephrite from which emitted anions promote not only metabolism in vivo and blood circulation but also excretion of waste products. The soft drink is obtained by adding and homogenizing 3-10% by weight of powdered nephrite which has a particle size ranging from 200 to 300 mesh to a beverage.

Description

Method for adding nephrite powder during the manufacturing process of soft drink and its products

The present invention relates to a method for adding nephrite powder during the manufacturing process of a soft drink, and a product thereof, that is, a beverage characterized in that fine powder particles of nephrite jade are added during the manufacturing process of various beverages. It relates to a manufacturing method and a product. More specifically, the present invention, by adding a fine powder of purgatory in the manufacture of beverages, in particular, water quality improvement, impurities removal ability (heavy metal removal ability), disease treatment ability of the human body (headache, indigestion, hand and feet, constipation, etc.) The present invention relates to a novel nephrite powder-containing beverage and a method for producing the same, which are endowed with excellent efficacy that can be widely used for drinking life.

As is well known, jade is roughly divided into jadeite and jadeite, and jadeite is a lead masonry mineral belonging to the pyroxene family. , Monoclinic system of soda, hardness is dense mass like crystal, light is black, cyan, green, transparent or semi-transparent, usually called jade Refers to this jadeite.

Nephrite jade is a monoclinic whiskey mineral of Inosilicates, which is divided into purgatory and serpentine superbasic purgatory among high quality surrogate rocks and their quality. Its fine structure, that is, the degree of fineness of hollowstone-positive stone sperm into fastenings and fibers is known, and the thinner the fiber, the better the quality.

According to a report published in the German authoritative medical literature (Mauda Palmer Die Verborgene KRAFF der KRISTALLE und der EDELSTEINE), jadeite and jadeite are two different ores, which, like most gems, contain silicon and coral, but jadeite is granular. Though it is formed of crystals, purgatory is composed of countless crystals such as fiber and hair and fine aggregates. Especially, purgatory is different from Natrium and aluminum composition of jadeite, which is beneficial to the human body. It has been reported recently that iron and magnesium have a major effect on the healing of diseases caused by high blood pressure, diabetes, circulatory disorders, heart disease and kidney disorders.

In Dongbobogam, a classic of oriental medicine, jade is added to Omiju and Jiyuju, and it turns into water, and it is good to eat when it is put in Hwangjangsu. When eaten at the same size as 豆 大, the waste is discharged to the outside of the body, 1 oxol and 1 jijicho (地 楡 草), 1 bream (稻米), and 3 egret (白露) are mixed together and put in a copper bowl. When it is built, the oxol turns into water, which is called oxal (玉液) and is called Shinseonokjang (神仙 玉 漿), and it is found in Sinnongboncho, Dangboncho, and mainogang rivers. According to the jade powder to make the enlightenment and taking it not only has the effect of moisturizing the five intestines and exhausting the waste in the body completely, but also removes the heat in the stomach is effective for the digestive system, bronchial asthma and Good for fever with fever and stuffy heart It will quench your thirst, and if you wear it with sesame seeds, it will make your body lighter and longer as you fly, lubricating your lungs, vocal cords, nourishing your throat, nourishing your hair, and functioning your intestines. It helps nourish and calm down the stressful neurological disorders.In addition, when the muscles are tense and the rats fly, they can eat white jade powder, and when there are scar marks on the face and body, rubbing the wounds with purgatory for several days will cause scars. The main ingredient of purgatory, such as disappearing, has been known since early to have an excellent effect on the human body without side effects.

Although purgatory is known to have such excellent medical effects due to its scarcity, it was limited to use as some jewelry for jewelry, such as necklaces, rings, and bracelets, and it is also economically disadvantageous because it is expensive. The development of general household goods which have been used has almost never existed, and thus its research and development is desperately required.

The inventors pay attention to the excellent medical effects of purgatory as described above, and at the end of each decade of research experiments, the manufacturing process of beverages, especially soft drinks such as cola, cider, juice-containing beverages such as juice, ion-containing beverages, milk the contained beverage when beverage manufacture of a health drink and coffee, black tea, such as drinks, fine particles purgatory minutes particular, two biotite Butch (負値) σ ¹⁸ 0 as in the high soil marble of (preferably not less than 200 mesh) When the prescribed purgatory powder is added, the prepared beverage not only shows excellent physical and medical effects such as improving water quality, removing impurities such as heavy metals, and treating the headache, constipation, numbness, indigestion, etc. The present invention has been found to be able to increase palatability as a mild flavored beverage.

Accordingly, the present invention has a main object to provide a novel beverage having excellent medical and physical efficacy, which can be widely applied to daily drinking life by using the excellent efficacy of the purgatory powder as described above.

Another object of the present invention is to maximize the use of jade powder and nephrite powder water treated with residues or wastes derived from mining or jewel processing of volatile jadeite with a specific composition.

Other objects and advantages of the invention will be apparent from the following description, and will be apparent from the examples.

According to one embodiment of the present invention, the sugar is added to purified water, and the syrup is filtered and sterilized. Then, 3-10% of fine purifying powder having a particle size of 200-300 mesh is added based on the total weight of the beverage, and mixed with low temperature. After cooling to provide a method for producing a soft drink comprising the step of injecting carbon dioxide. Optionally, flavors such as fruit flavors, fruit juices, milk, dietary fiber, ionic substances beneficial to the human body, and the like may be added. In addition, the same method can be applied to a variety of beverages, such as health drinks, such as drinks, coffee drinks, green tea.

According to another embodiment of the present invention, in the method of preparing fruit juice comprising the process of raw material selection, washing, grinding, juice, vacuum treatment, filtration and sterilization, the particle size of the juice is preferably 250 to 300 mesh. There is provided a method for preparing juice comprising adding a purgatory powder having an amount of 3 to 10% of the total weight of the product. At this time, a sugar, an organic acid or a flavor may be suitably combined with natural fruit juice, and it is also preferable to adjust sugar concentration, for example, 12-13 degrees Brix, and organic acid concentration, for example to 0.4-0.5%.

The method for preparing a beverage in the present invention can be changed by those skilled in the art in various ways depending on the characteristics of the material or the use of the product, it is not limited to the above embodiment.

The particle size of the nephrite powder used in the present invention is preferably at least 200 mesh, more preferably at least 250 mesh, in view of the taste and feel of the beverage. The addition amount of the nephrite powder is suitable in an amount of 3 to 10% based on the total weight of the beverage product. If the content of the purgatory powder is less than 3%, the effect due to the addition of the purgatory powder cannot be expected, which is not preferable. There is a fear that the homogeneity of the beverage is not only difficult, but also the product price is increased due to the high price of the purgatory powder, so the content is 10% or less.

According to the present invention, the beverage product to which the nephrite powder is added may be economically advantageous in terms of cost reduction, since it is possible to use the nephrite powder to make products such as sculptures and to wash and finely grind remaining residues.

The nephrite powder used in the present invention is defined as butch σ ¹⁸ 0 as hollow glare in the high quality surrogate rock, and it is most preferable to have a composition ratio as shown in Table 1 below.

TABLE 1

Semi-quantitative Analysis of Oxygen Samples of the Invention

(Semi-Quantitative Analysis) (%)

According to the present invention, the preparation of the beverage product to which the nephrite powder is added and the effects exhibited in the product are described in detail in the following Examples and Experimental Examples.

Example 1

Fresh ripe tangerines are selected and washed in water with 0.3% hydrochloric acid to remove residual pesticides and soil, and peeled and then pressed to squeeze out the juice. The sugar content of the fruit juice is maintained at 12.0 ° Brix and the acidity is 0.6-1.1%. Then, 3-7% of the jade powder with a particle size of 250-300 mesh is added to the drink, followed by mixing and homogenization. The fruit juice added with the purgatory powder is sterilized at 85-90 ° C. for 35 seconds and then injected into a container to be sealed and cooled to 40 ° C. or lower and stored.

Experimental Example 1

In this Experimental Example, 50 ml of juice prepared in Example 1 were prepared in the same manner as 50 ml of men and women over 10 years of age in order to investigate palatability, touch, etc. 50 ml (non-contained) juice containing no tasting was allowed to the tester unknowingly and evaluated palatability. The results are shown in Table 1 below.

TABLE 1

As shown in the above experimental results, the juice added with purgatory powder proved to be superior to or comparable to the control juice in terms of consumer preference.

Experimental Example 2

In the present experimental example, the effect of jade water (mineral water) added with tap water of the present invention on tap water on the growth development and hardness of silkworm was examined (the results of the Korean Society of Cattle Science).

① Materials and Methods

1. Disclosed silkworm breed: Baekokjam

2. Breeding time: hatching the side immersion of late harvest species (November-December)

3. Breeding method: constant temperature and humidity, heraldic mulberry leaf meat

4. Number of Disclosures: Contrast-150 two 2 repetitions

Processing-130 two 2 repetitions

5. Contents of treatment: Control-distilled water sprayed mulberry

Treatment-Mulberry Feeding by Spraying Purity

Processing Period: From 2nd Stage Sleep

[Table A]

Breeding Results by Oxygen Water Treatment

[Table I]

Thread extraction from cocoon with jade water treatment

[Table]

Changes in Larvae Weight due to Jade Treatment

[Table D]

Reduced Blood Glucose Level by Jade Solution

◎ Result

1. In larval weight, the soft corn treatments were heavier than the control distilled water treatments, especially 0.48 g / kg.

2. The rate of fire was 71.2%, which was 15% lower than that of the nephrophyte, and 15.4g of 10,000 head was 7% lower than the control.

3. The total weight of the nephrophylls was 2.14g, which was 6% heavier than the control and 44.5cg, which was 9% heavier. The silk ratio was 2% higher than the control.

4. Purgatory feeding showed better overall performance than control. In particular, the length of the silk was long, the amount of silk was high, and the rate of hatchery was much higher than that of the control by about 9%.

5. In the sands, nephrophyllum larvae were slightly thicker, and the ratios of strength, elongation, and yield were higher than those of the control.

6. There was no significant difference in silk surface structure between control and treatment.

7. The hypoglycemic effect of Purgella silkworm larvae was 70.3%, 24% higher than the control.

8. The crystal structure of the nephrite nephrite had a rod-like structure with a sharp end.

Experimental Example 3

In the present experimental example, the activity change of the mice drinking the drinking water of drinking water (living water) of the present invention was observed.

Experimental results As shown in the diagram below, the mice in the positive control group began to stabilize the central nervous system from 5 minutes after drinking Uvabito (Note: Chinese name) medicine, and gradually returned to normal after 30 minutes. Mice in the control group showed activity ups and downs and overall decline.

The activity rate of the drinking test group (mouse) of jade flour drinking water of the present invention was similar to that of the general control group, but compared to the average of the overall activity rate was higher than that of the general control group, it can be seen that there is a more significant difference compared to the positive control group. .

Comparison

Changes in Activity of Rats Drinking Oxygen Drinks by the Matrix of the Present Invention

Experimental Example 4

50 adult men and women who complained of symptoms such as headache, numbness, indigestion, constipation, or diagnosed were to continue taking the juice prepared in Example 1 of the present invention 200 days a day or more for 20 days The effect was evaluated. The results are shown in Table 2 below (Department of Oriental Hospital Hospital, Daejeon University).

TABLE 2

As shown in the experimental results, when the beverage of the present invention is ingested, headache (83%), constipation (94%), hand and feet (75%), indigestion (89%) was found to be alleviated.

Experimental Example 5

This experiment tests for the presence of lead, heavy metals and other toxic components in the jade powder added to the present invention.

TABLE 2

(Lead content test)

TABLE 4

(heavy metal)

TABLE 5

(Inorganic elution test)

100 g of the sample was extracted with 1 liter of water by autoclave treatment, and the extract was analyzed.

As shown in the above experimental results, purgatory powder used in the present invention has no lead, heavy metals, and other toxic components harmful to the human body, and thus stability has been proved when added to a beverage.

Experimental Example 6

This experimental example shows the process and results of the experiment conducted by Inha University bioinformatics system engineering laboratory to investigate the various effects of jade powder on the living body.

In this experiment, 70% of the constituent elements of the human body are water, so it was determined that there would be many relations between the change of water and the effect on the human body. The experiment was performed.

end. Hard water change

Experiment 1

100 ml of artificially hard water was transferred to each of the four flasks in 50 ml, and the purgatory was placed at the bottom of two flasks for about 10 minutes.

To determine the change in hardness, a titration method using EDTA (titer 2.9412) was used. 1 ml of a buffer solution of pH 10, EBT was used as an indicator.

The change in hardness was measured by the amount of EDTA until the moment when the color of the hard water was changed by EDTA. At this time, the color returned to its original state over time, but in this experiment, the measurement was made based on the changing moment.

Result 1

At 100ppm of hard water, it takes 1.70ml of EDTA.

It takes 1.25ml of EDTA after purgatory test.

Thus, the 100.00 ppm hardness is lowered to 73.53 ppm.

In other words, the 10.00 ppm hardness softened 26.47%.

Experiment 2

200ml of 100ppm hard water made by the same method as in Experiment 1 was transferred to a beaker to soak the purgatory.

After about 30 minutes, the water in the beaker was divided into three flasks to measure the change in hardness. In this experiment, for more precise experiments, the hardness was measured by adding EDTA until the color of hard water did not change any more after the color of hard water changed by EDTA.

Result 2

Each 100ppm hard water before purgatory experiment

89.62 ppm

91.19ppm

89.62 ppm

90.14 ppm average

Thus, 9.9% hardness decreases

Experiment 3

This experiment was conducted with tap water. The tap water was placed in a container and transferred to six flasks. The purgatory was placed at the bottom of three flasks, and the hardness was measured about 5 minutes later.

Result 3

Tap water without purgatory

97.48 ppm

97.48 ppm

97.48 ppm

Average 97.48 ppm

Tap water after purgatory experiment

91.19ppm

91.19ppm

91.19ppm

91.19 ppm average

Thus, 6.5% hardness reduction

I. Effect of Purgatory on the Proliferation of Digitalis lanata Suspension Plant Cells

① Effect of Purgatory on Digitalis lanata Cell Growth in Growth Medium

[Figure 1]

Total volume change of culture medium of cells proliferating in growth medium

[Figure 2]

Cell volume changes

[Figure 3]

Change in cell biomass

[Figure 4]

Change in Dry Weight of Cells

In Figures 1 to 4 shown in the table, Figure 1 shows the change in the total volume of the culture medium of the cells growing in the growth medium for 11 days. Since the depletion of the media components and the evaporation of the media occurs in proportion to the increase of the cells growing over time, the overall volume change of the culture medium reflects these factors. In particular, humidity and temperature in the atmosphere are closely related to evaporation of the medium, and such factors also affect the rate of cell growth. As shown in the figure, the use of nephrite shows a slight decrease in the volume of the whole culture compared to the unused control. This is because the use of purgatory rather than the control has a faster cell growth rate against the evaporation of the medium or the depletion of nutrients. This phenomenon is observed in the case of continuously purifying the cells from day 4 to day 11 after inoculation of cells, as shown in Figure 2, which measures the volume change of only the submerged cells. This fact can be estimated. Therefore, the use of nephrite showed a faster cell growth rate than the control without the nephrite. This result can be said to be the result of delaying the decrease of the total volume than the control by offsetting the decrease of the total culture volume due to nutrient depletion and medium evaporation. In addition, the result of comparing the volume of the increased cell alone is also observed to show a tendency to gradually increase the cell volume after 4 days, it is thought that can support this result.

Cell proliferation and dry weight are the most common measures of cell proliferation. In general, the growth curve of all cells is represented by the S-shaped curve, which can be classified into four stages. The period of adaptation to the medium is the lag phase, in which there is no cell proliferation and no mass increase, and the exponential phase, which shows a curve with a steep slope due to the mass increase at a rapid proliferation rate after this period. As the proliferation slows down, the stationary phase shows no mass increase, and the total cell volume or mass tends to rupture and die due to depletion of nutrients, discharge of toxic components, and saturation of cell density. It can be divided into decreasing dead phase.

Figures 3 and 4 show the results of measuring cell biomass and dry weight. Figure 3 follows the four growth curves. In the case of using jade, after 7 days, the growth rate was slightly higher than that of the control without jade, and the growth stopped until 10 days, unlike the control showing the decrease in cell biomass. have. This is remarkable in that cell growth is continued even when the nutrient is almost depleted and the concentration in the medium becomes zero compared with the change in the concentration of glucose, a nutrient that acts as the main metabolic substrate in the medium. Do. It is common to show a tendency to stop the growth and decrease the growth rate at this point of time when nutrients are depleted, such as the control without the purgatory. However, when using the purgatory, it shows a different phenomenon. It is assumed to be. These results are also shown in the cell dry weight measurement in Figure 4, showing cell growth proliferating at a higher rate than the control group after day 3, and the same phenomenon as in Figure 3 from day 9 thereafter.

As a result, cells grown close to purgatory in growth media showed a better effect on cell growth than controls that did not. Digitalis lanata plant cells, which have a growth limit of about 10 days, are maintained in a stable state without cell necrosis even after 10 days of incubation with nephrite without replacement with fresh medium. Because of this phenomenon, it is expected to be applied as an advantageous method for optimizing cell growth and concentration in the production process for producing useful substances.

② Effect of Purgatory on Changes in Medium pH

[Figure 5]

PH change in cell growth medium

[Figure 6]

PH Change in Production Medium after Adding Purgum Powder

Figure 5 shows the changes in media pH in the growth media with and without purgatory. The control group shows a general tendency of pH in the medium applied to plant cells, which gradually decreases over time and is maintained at a certain level. However, by using the purgatory, it showed a similar tendency to the control group until the 7th day and increased gradually. This phenomenon is extreme from the result in Fig. 6 which shows the result in the production medium in which the purgatory powder was added directly to the culture medium. have. The control group without added jade powder shows a consistent drop in pH, whereas the addition of jade powder shows a tendency to maintain the value to some extent. It is assumed that it acts as a cause.

③ Results of analysis of water quality for purgatory

Tables A and B show the states of the analytical instruments and the results of the analysis. The data from these are summarized in Table C in Table C. Table C is a measurement of each analysis item after 48 hours (Sample 1) to put 20g of jade jade mass in solution. In this table, there is no change in each measurement item, and the effect of purgatory does not appear. Table D shows the measured values for each analysis item after 48 hours (Sample 2) by placing 20g of purgatory lumps outside the solution. Table F also showed no change for each analysis item even if purgatory was placed outside the solution (Sample 4). However, in case of Sample 3, the data measured for each analysis item of the sample 48 hours elapsed after adding 20 g of nephrite powder in the solution is shown in Table E. There are many changes that can be seen in this table. As follows.

Cr, Pb, Ni, and Co, which are harmful to the human body, changed significantly after 48 hours. Cr was removed in the absence of purgatory powder, that is, 45.30 mg before the reaction was removed to 0 after 48 hours in the purifying powder, and Pb was also completely removed from 13.76 mg to 0. Ni decreased from 51.8 mg to 1.733 mg and Co (II) also decreased from 52.69 mg to 11.94 mg.

Mg, one of the essential elements in the human body, increased from 48.36mg to 55.74mg.

The hydrogen ion concentration of distilled water was acidic to pH 3.5, but after the reaction, it was neutralized to pH 6.8, and the conductivity decreased rapidly. Adsorption force is physically large, about 3-4 mmol.q (equivalent) per gram.

TABLE A

Status condition of analyzer

[Analysis B]

Output of analysis results

TABLE C

Purification results before and after the reaction in solution Purgatory lumps in solution

Sample: Purgall lump in solution (20g)

TABLE D

Analysis result when purge lump is placed outside the solution

Sample: Purgall lump (20g) out of solution

TABLE E

Analysis result when adding purgatory powder to solution

Sample: Purgatory powder in solution (20g)

TABLE F

Analysis result when purifying powder outside solution

Sample: Purified powder outside solution (20g)

As described above, the digitalis lanata plant suspension cells cultured for one week with nephrite close showed proliferation of about 30% or more without purgatory. This is a rare proliferative result even in various experiments performed for the proliferative effect on conventional Digitalis lanata plant cells for high concentration culture.

In addition, experiments on how purgatory water affects hard water showed that purgium softened hard water without contact with water.

Particularly, in the component analysis experiments on water using distilled water, the jadeite was precipitated, and after 48 hours, in the component analysis, the pH was increased, the Ni and Co components were reduced, the Cr and Pb were removed, and the heavy metals were removed. An unusual phenomenon was observed that led to the phenomenon of.

As such, purgatory and nephrite powders according to the present invention have not yet been clearly identified theoretically, but change the hardness of water without contact with water and proliferate more than 30% of Digitalis lanata plant suspension cells, Ni, The elimination of heavy metals harmful to the human body, such as the reduction of Co components and the removal of Cr and Pb, is believed to be due to the radiation effect of the electromagnetic wave wavelengths of the nephrite powder and the ionic reaction by the mineral components contained in the nephrite. This is also believed to be evident by the efficacy exhibited in the above-described experimental examples and products according to the present invention.

In addition, the experimental results as described above, in the case of the beverage containing the purgatory powder of the present invention due to the effect of purgatory, water quality improvement such as removal of heavy metals, control of pH and softening of hard water and the improvement of flavor and removal of impurities, In particular, it suggests that there are effects such as medical efficacy.

Claims (2)

A method of producing a beverage, the method of producing a soft drink by adding a homogeneous powder of pulverized fine particles having a particle size of 200 to 300 mesh to 3 to 10% by weight and homogenizing. Soft drink, characterized in that 10% of fine purpurum having a particle size of 200 to 300 mesh is added.