JP2007028973A - Method for forming dry powdered seaweeds into superfine particle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for forming dry powdered seaweeds into superfine particles for increasing absorbing efficiency into the human body through forming the dry powder seaweed processed by a conventional well-known method into superfine particles of nanometer size. <P>SOLUTION: This method for forming the dry powdered seaweeds to superfine particles comprises pulverizing the dry powder seaweed processed by a conventional well-known method into particulate seaweed particles, admixing the powder seaweed particles with electrolyzed reduced water which has characteristics of containing no chlorine, having an oxidation-reduction potential of ≤200 mV and containing active hydrogen, and stirring and mixing the mixed liquid and bring the adjusted liquid into a fluid product. Furthermore, the method comprises pumping the fluid product to a superfine particle-forming apparatus, eliminating active oxygen which is generated with active hydrogen in the electrolyzed reduced water during a superfine particle forming process, crushing the whole powder seaweed particles into superfine particles of nanometer size without deteriorating active components so as to extract the active components from the powder seaweed particles formed into superfine particles in the fluid product, and drying the fluid product by a drying machine to take it out as the dry powder seaweed. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

The present invention degrades the active ingredients of each material of the seaweed, such as dried powder seaweed that has been processed into a powder form by a conventionally known method, such as seaweed such as kombu, seaweed, paste, hijiki, spirulina, and blue seaweed. Without, for example, nanometer-sized to make ultrafine particles, extract the active ingredients such as vitamins, minerals, etc., and when eating the ultrafine powdered seaweed as food, the absorption to the human body The present invention relates to a method for making ultrafine particles of dry powder seaweed that can be enhanced.

Conventionally, processed foods in which seaweeds such as kombu, seaweed, seaweed, hijiki, spirulina and blue seaweed are used as dry powder seaweed are commercially available. Moreover, the following patent document 1 is well-known when the past patent document is searched retrospectively about the method of using seaweed as a dry powder.

JP 2000-245403 A

Processed foods in which the seaweed such as kombu, seaweed, seaweed, hijiki, spirulina, and blue seaweed are dried powder seaweed by a conventionally known method are not micronized to nanometer size, for example, so Extraction of active ingredients of seaweeds such as these is insufficient, and when these are eaten as so-called health foods, there is a problem that the absorption of the active ingredients held by seaweeds to the human body is poor.

Further, what is disclosed in Patent Document 1 relates to a method for treating seaweeds, there is a description that seaweeds are made into a dry powder, but the seaweed dry powder is, for example, ultrafine to nanometer size. Therefore, even if the seaweed powder is eaten, there is a problem that the absorption of the active ingredients such as minerals and iodine held by the seaweed is poor.

The present invention has been made to solve the above-mentioned problems. For example, as described in Patent Document 1, dry powder seaweed processed into a powder by a conventionally known processing method is converted into an ultrafine particle device. For example, by making ultrafine particles down to nanometer size, active ingredients such as minerals and iodine are extracted, and when they are eaten as food, they are made into ultrafine particles, so that they can be absorbed into the human body. It is an object of the present invention to provide a method for making fine particles of dry powder seaweed that can be produced.

The present invention pulverizes dry powder seaweed processed into powder by a conventionally known processing method to form fine powder seaweed particles, and the powder seaweed particles and tap water or natural water. Electrolytically reduced water that does not contain chlorine obtained by electrolysis, has an oxidation-reduction potential of 200 mV or less and contains active hydrogen, or any of alkaline ionized water, mineral water, or pure water The mixed fluid is pumped to a micronizer at high pressure, the fluid containing the powdered seaweed particles is collided under high pressure, and the powdered seaweed particles are crushed into ultrafine particles. Extracting the active ingredients such as mineral and iodine into the flow material, drying the flow material with a dryer and evaporating the water in the flow material to remove the active ingredients such as mineral and iodine. Preventing deterioration, ultrafine dry powder sea By adopting the method of retrieving the like, the above-mentioned problems are eliminated.

According to the method for making ultrafine particles of dry powder seaweed of the present invention, dry powder seaweed processed into powder by a conventionally known processing method is finely pulverized into fine powder seaweed particles, and the powder Electrolytically reduced water or alkaline ionized water that does not contain chlorine obtained by electrolyzing seaweed particles and tap water or natural water, has an oxidation-reduction potential of 200 mV or less, and contains active hydrogen, A fluid mixed with either mineral water or pure water is pumped to an ultrafine atomizer at high pressure, and the fluid containing the above-mentioned powdered seaweed particles is collided under high pressure to produce a powder. The seaweed particles are crushed and made into ultrafine particles, for example, to a nanometer size, and active ingredients such as minerals and iodine are extracted into the fluid, and then the fluid is dried with a dryer. Evaporate the water in the flow Removed by It, minerals, to prevent degradation of the active ingredient of iodine or the like, it is possible to finely divided dry powder seaweed.

Then, when the dried powder seaweed processed into ultrafine particles is made into a tablet or granule, it is collected as a health food and becomes ultrafine compared to the conventional dry powdered seaweed. Therefore, the absorbability to a human body is high, and active ingredients, such as a mineral and an iodine, can be absorbed into a human body efficiently.

The best mode for carrying out the present invention will be described in detail. The present invention relates to dry powder seaweed obtained by processing seaweed such as kombu, seaweed, seaweed, hijiki, spirulina, blue seaweed, etc. into a powder form by a conventionally known method, and fine powder seaweed particles. The seaweed particles may be either electrolytically reduced water that does not contain chlorine, has an oxidation-reduction potential of 200 mV or less and contains active hydrogen, or alkali ion water, mineral water, or pure water that does not contain chlorine. A predetermined amount of water is added and mixed to form a fluid containing powdered seaweed particles, which is pumped to a micronizer at high pressure, and the fluid containing powdered seaweed particles is subjected to high pressure. Colliding and crushing the powdered seaweed particles into ultrafine particles, and extracting the active ingredients such as minerals and iodine into the flow, and then the flow containing the ultrafine powdered seaweed particles Dry the product with a dryer. Te was removed by evaporation of water in the flow-like material, and finely divided dry powder seaweed.

The method for making fine particles of dry powder seaweed according to Example 1 of the present invention uses dry seaweed that uses electrolytic reduced water that does not contain chlorine, has an oxidation-reduction potential of 200 mV or less, and contains active hydrogen. This is an ultrafine particle method. And the 1st process of the ultrafine particle | grain method of the dry powder seaweed by Example 1 is a conventionally well-known processing method, for example, the said patent document 1, seaweeds, such as kombu, seaweed, paste, hijiki, spirulina, and blue paste. This is a fluidization step for producing a dry powder seaweed by the processing method disclosed in Japanese Patent Application Laid-Open No. 2000-245403 described above and converting the dry powder seaweed into a fluid.

That is, in the first step, the dry powder seaweed processed by the conventionally known method is pulverized by a pulverizer or the like and is not particularly limited, but preferably a fine particle powder having a particle size of 50 μm or less. The seaweed particles are obtained. After that, 15 to 25% by weight, preferably 20% by weight, of the powdered seaweed particles are obtained by electrolyzing tap water or natural water, and do not contain chlorine and have a redox potential. The powdered seaweed is prepared by adding and mixing in 75 to 85% by weight, preferably 80% by weight, of electroreduction water having a characteristic of containing 200% or less of active hydrogen and mixing and stirring the mixture. In this step, the particles are adjusted so as to be evenly dispersed in the electrolytically reduced water to obtain a flow of powdered seaweed particles and the electrolytically reduced water.

In the present invention, the electrolytically reduced water is used, particularly in the case of tap water, because it is oxidized by chlorine contained in tap water, and active ingredients such as minerals and iodine in seaweed deteriorate. In order to obtain high-quality ultra-fine dry powder seaweed by utilizing the above-mentioned properties possessed by electrolytically reduced water in the processing step of the present invention. is there.

The electrolytic reduced water used in the present invention is not particularly limited, but preferably, tap water using, for example, “Trim Ion TI-8000”, which is an electrolytic reduced water adjuster manufactured by Japan Trim Co., Ltd. Electrolytically reduced water is used among electrolytic acid water and electrolytically reduced water produced by electrolyzing. It is known that the electrolytically reduced water produced by the “trim ion TI-8000” has an alkaline pH of about 9.6, an oxidation-reduction potential of about −274 mV, and contains active hydrogen.

The “electrolytically reduced water” is water obtained by electrolyzing tap water using an electrode plate obtained by calcining platinum on titanium, and is a water rich in active hydrogen having a reducing power. Water with the ability to erase active oxygen.

Usually, two hydrogen atoms (H) are bonded together and exist as hydrogen molecules (H ₂ ), but hydrogen does not exist as molecules, and atoms are present as active hydrogens. is there.

On the other hand, active oxygen is thought to cause various diseases, destroys clean cells from its strong oxidizing power, and causes illness and aging. Active oxygen is in an electrically unstable state with one electron less than normal oxygen, and tries to take electrons from normal cells (oxidation). In this way, the cells that have been deprived of electrons are oxidized and killed.

As described above, active hydrogen is electrically unstable due to the atomic state of hydrogen, but the active hydrogen is associated with electrically unstable active oxygen that causes various diseases. , Harmless (H + O = H ₂ O) and discharged outside the body. That is, active hydrogen has the ability to erase active oxygen.

The second step of the processing method of the present invention is an ultrafine particle forming step of powder seaweed particles. That is, in the second step, the powder seaweed particles obtained in the above step and the electrolyzed reduced water are removed from the whole powdered seaweed particles in the fluid using a conventionally known ultrafine atomizer. This is the process of making ultrafine particles down to nanometer size.

A conventionally known apparatus can be used as the ultrafine particle forming apparatus. In the present invention, there is no particular limitation, but preferably, an “emulsifying device” conventionally known as, for example, Japanese Patent No. 2788010 shown in FIGS. 1 to 8 is used as an ultrafine particle forming device of the processing method of the present invention. It is recommended to do.

That is, as shown in FIG. 1, the ultrafine particle device M is configured to supply the fluid supply tank 11, the high-pressure pump 12 that pressurizes the fluid, and the fluid that is pumped from the high-pressure pump 12. Ultrafine particle member 13 that collides under high pressure to crush powder seaweed particles to form ultrafine particles down to nanometer size, and ultrafine powdered seaweed discharged from ultrafine particle member 13 It is comprised by the storage tank 14 which stores the fluid containing a similar component.

The ultrafine particle member 13 is housed in a casing 15 in which a first disk 16 and a second disk 17 are closely fixed, and these disks 16 and 17 have the above-mentioned flow shape on the plate surface. Through-holes 16a, 16b and 17a, 17b having widths through which objects can pass, and slit-shaped guide grooves 16c, 17c connecting the through-holes 16a, 16b, 17a, 17b are formed, respectively. 18, a guide path 19, a mixing chamber 20, and an outflow path 21 are formed.

The first and second disks 16 and 17 will be described with reference to FIGS. 2 to 6. The disks 16 and 17 have the same diameter by a wear-resistant material such as a sintered diamond or a single crystal diamond. Is formed.

As shown in FIGS. 2, 3 and 6, the first disc 16 has inflow through holes 16 a and 16 b having the same diameter in a vertically symmetrical position with respect to the center of the plate surface. A first guide groove 16c that communicates the end portions of the through holes 16a and 16b facing each other is formed in the contact surface with the two-disc 17.

As shown in FIGS. 3 to 7, the second disc 17 has a second surface so as to be orthogonal to the first guide groove 16 c of the first disc 16 on the close contact surface with the first disc 16. A guide groove 17c is formed, and outflow through holes 17a and 17b having the same diameter are formed at both ends of the second guide groove 17c.

The first and second discs 16 and 17 having the above-described configuration are closely overlapped so that the first guide groove 16c and the second guide groove 17c are orthogonal to each other in a cross shape, and the first cylindrical body 22 and the second disc The cylindrical body 23 is housed and fixed in a casing 15 formed by integrally connecting the cylindrical body 23 with bolts 24, whereby the ultrafine particle member 13 is formed. An opening 22 a on one side of the first cylindrical body 22 constituting the casing 15 is connected to the high-pressure pump 12, and an opening 23 a on the other side of the second cylindrical body 23 is connected to the storage tank 14. Has been.

In the casing 15, the first guide groove 16 c and the second guide groove 17 c of the first disc 16 and the second disc 17 which are closely superposed and fixed are orthogonal to each other in a cross shape, and the first and second circles are formed. A mixing chamber 20 is formed at the center of the plates 16 and 17. The inflow through holes 16a and 16b pass through the inflow path 18, the first guide groove 16c through the guide path 19 toward the center, and the second guide groove 17c and the outflow through holes 17a and 17b through the outflow path 21. Respectively. Therefore, as shown in FIG. 8, a liquid passage through which the fluid flows is formed in the order of the inflow path 18, the guide path 19, the mixing chamber 20, and the outflow path 21.

In the figure, 16d and 17d are positioning through holes provided in the first and second discs 16 and 17, respectively, and the first and second discs 16 and 17 are closely polymerized and fixed. When the first through second positioning holes 16d and 17d are polymerized so as to be able to pass through, and pins or the like (not shown) are fixed to the respective positioning through holes 16d and 17d. The two guide grooves 16c and 17c can accurately fix the first and second disks 16 and 17 orthogonally in a cross shape.

The operation of the ultrafine particle device M having the above-described structure will be described. The flow material containing the powdered seaweed particles charged in the supply tank 11 is converted to an ultrafine particle member 13 by a high-pressure pump 12 at a pressure of about 130 MPa. Is pumped to the opening 22a on one side of the casing 15 constituting the. The flow material fed to the opening 22a on the one side flows at a higher speed than the two inflow through holes 16a and 16b of the first disc 16, and further flows into the inflow through hole 16a. A high-speed flow flows in the inflow path 18 formed by 16b and both ends of the first guide groove 16c, and then formed by the plate surface of the second disc 17 and the first guide groove 16c. The flow direction is changed to the guide paths 19 and 19 with opposite pumping directions.

The flow material in which the flow direction is changed is two flows of the flow material whose pumping directions are opposite to each other in the mixing chamber 20 formed in the center portion where the first guide groove 16c and the second guide groove 17c are orthogonal to each other. Violently collides and changes the direction of the second guide groove 17c perpendicular to the cross shape by 90 degrees, the flow material collides and turbulence, and further collides with the wall surface of the second guide groove 17c to cause cavitation (cavity). Phenomenon).

And while the cavity part of this cavitation collapses, a very high pressure difference is caused locally, and the solid particle (powder seaweed particle) in the said fluid is crushed. This solid particle crushing phenomenon occurs within a very short time of several microseconds, and powerful energy is instantaneously added to the flow material. This energy makes the entire powdered seaweed particles ultrafine to nanometer size, for example. Extraction of active ingredients such as minerals and iodine in the powdered seaweed particles is performed.

When the fluid containing the powdered seaweed particles collides at a high pressure and momentary energy is applied to the fluid, water molecules are decomposed to generate strong active oxygen such as OH radicals, Active oxygen reacts with active ingredients such as minerals and iodine in the powdered seaweed particles, and these active ingredients deteriorate. Therefore, in the present invention, since electrolytically reduced water containing active hydrogen is used, the active oxygen generated in the ultrafine particle work is eliminated with active hydrogen, thereby degrading active ingredients such as minerals and iodine. And high quality dry powder seaweed can be obtained.

As described above, by converting the entire powdered seaweed particles into ultrafine particles, the flow material from which the active ingredients have been extracted is the second guide groove 17c, the plate surface of the first disk 16, and the outflow through holes 17a. -It discharges to the outflow path 21 formed by 17b through the opening 23a on the other side of the casing 15 without difficulty and is stored in the storage tank 14. Even while passing through the outflow path 21, the flow material collides with the wall surface of the second guide groove 17c, that is, the wall surface of the portion facing the mixing chamber 20 and the end wall surface communicating with the outflow through holes 17a and 17b. As a result, the formation of ultrafine particles further proceeds.

In the ultrafine particle device M, two discs 16 and 17 are densely superposed and arranged in a flow path of a fluid, and slit-shaped guides formed on the superposition surfaces of the discs 16 and 17 are arranged. While letting the flow material pass through the grooves 16c and 17c and changing the flow direction, the powder seaweed particles are crushed by colliding with the wall surface and colliding with the flow materials, and the powder seaweed The entire structure is formed into ultrafine particles, discharged outside the casing 15 and stored in the storage tank 14.

When the ultrafine particleization of the powdered seaweed particles introduced into the ultrafine particle generator M does not reach a predetermined particle size, for example, nanometer size, the fluid once stored in the storage tank 14 is The powder is fed into the opening 12a by the high-pressure pump 12 and introduced into the ultrafine particle device M a plurality of times, and the ultrafine particle formation process is repeated to obtain powdered seaweed particles that have been finely divided to a predetermined particle size. be able to.

In addition, when the ultrafine particle forming step is repeated a plurality of times, the surface area of the whole powdered seaweed particles increases as the fine particle size is increased, so that the moisture ratio decreases. Further, the active hydrogen disappears in a short time, and if necessary, a small amount of the electrolytically reduced water is newly added, for example, 2 to 10% by weight, preferably 5%. About 5% by weight is additionally mixed in the flow material, and the water ratio is increased to achieve smooth pumping to the opening 12a. Ultrafine particles may be formed by erasing active oxygen generated again by the fine particle formation step.

Furthermore, when the electrolyzed reduced water is alkaline having a pH of about 9 to 10 , the extraction efficiency of active ingredients such as minerals and iodine can be further increased in the ultrafine powdered seaweed particles. Most of the active ingredients are extracted into the flow.

The third step of the processing method of the present invention is a drying step. That is, in the third step, the fluid obtained by extracting the active ingredient from the powdered seaweed particles that have been microparticulated in the second step is dried by a dryer to evaporate the water in the fluid. Is removed and removed as a massive dry powder seaweed containing the extracted active ingredient.

In the processing method of the present invention, the drying by the dryer may be any one of the drying methods such as heat drying using a spray dryer or roaster, low temperature drying using a low temperature dryer, or freeze drying using freeze drying. However, in order to prevent deterioration of active ingredients such as minerals and iodine, low temperature drying using a low temperature dryer or freeze drying using freeze drying is recommended.

The 4th process of this invention processing method is a crushing process of dry powder seaweed. That is, in the fourth step, the dry powdered seaweed after the water evaporated through the drying step in the third step is agglomerated, so that the dry powdered seaweed is a powdery final product or tableted. In order to obtain a final product such as a tablet, the pulverization of the agglomerated dry powder seaweed is performed to a predetermined particle size using a pulverizer or the like.

After the completion of the fourth step, for example, in the case of making a health food made of 100% dry powdered seaweed that has been microparticulated, the dry powdered seaweed that has been microparticulated can be packaged as it is, When the dried powder seaweed is added and mixed with other ingredients to obtain a health food, for example, it is tableted by a tableting machine to obtain a tablet-like product.

Next, in the method for making ultrafine particles of dry powder seaweed according to Example 2 of the present invention, any of alkaline ionized water, mineral water, or pure water not containing chlorine is used instead of the electrolytically reduced water used in Example 1. It uses that water. When water containing chlorine such as tap water is used, active ingredients such as minerals and iodine are oxidized and deteriorated by the chlorine, and this is prevented, and contamination of impurities is prevented. In order to obtain the powdered seaweed, any one of the alkali ion water, mineral water, or pure water containing no chlorine is used.

The alkaline ionized water is negative water produced by electrolyzing tap water using a commercially available alkaline ionized water generator, and is preferably alkaline having a pH of about 9 to 10. By using this, the extraction efficiency of active ingredients such as minerals and iodine can be enhanced. Moreover, the mineral water uses what is marketed, Furthermore, pure water uses what was manufactured with the pure water manufacturing apparatus.

And as a method for making fine particles of dry powder seaweed according to Example 2, the second step is slightly different from the method of making fine particles of dry powder seaweed of Example 1, and the other steps are the same. . That is, in the second step in Example 2, the electrolytically reduced water of Example 1 does not contain chlorine obtained by electrolyzing tap water or natural water, has an oxidation-reduction potential of 200 mV or less, and is active. Alkaline ion water, mineral water, or pure water used in Example 2 is water that does not contain active hydrogen, whereas it is water that contains hydrogen, and is generated at the time of collision of a fluid containing powdered seaweed particles. Although there is no action of erasing the active oxygen as in Example 1, the quality is only slightly inferior to that of Example 1 and there is no inferiority even when used as food.

In Example 2, as in Example 1 above, when the ultrafine particle forming step is repeated a plurality of times until the powdered seaweed particles having a predetermined particle diameter are obtained, the powder becomes finer as it becomes finer. Since the water ratio decreases due to an increase in the surface area of the entire seaweed particles, there is a possibility that clogging may occur due to the fact that it cannot be smoothly pumped to the opening 12a. In addition, a small amount of mineral water or pure water, for example, 2 to 10% by weight, preferably about 5% by weight, is additionally mixed in the flow material to increase the water ratio and achieve smooth pumping to the opening 12a. Alternatively, ultrafine particles may be formed.

1 is an overall system diagram of an ultrafine particle forming apparatus used in an ultrafine particle forming method for dry powder seaweed of the present invention. It is a schematic longitudinal cross-sectional view of the ultrafine particle formation apparatus used in the ultrafine particle formation method of this invention dry powder seaweed. It is a right view of the 1st disk which comprises the ultrafine particle formation apparatus used in the ultrafine particle formation method of dry powder seaweed of this invention. It is AA longitudinal cross-sectional view of FIG. It is a left view of the 2nd disk which comprises the ultrafine particle formation apparatus used in the ultrafine particle formation method of dry powder seaweed of this invention. It is BB longitudinal cross-sectional view of FIG. It is a perspective view of the 1st disk and the 2nd disk which constitute the ultrafine particle formation device used in the ultrafine particle formation method of the dry powder seaweed of the present invention. It is a longitudinal cross-sectional view of the principal part of the ultrafine particle formation apparatus used in the ultrafine particle formation method of dry powder seaweed of this invention.

Explanation of symbols

M: Ultrafine particle device 13: Ultrafine particle member 16: First disk 16a, 16b: Through hole 16c: First guide groove 17: Second disk 17a, 17b: Through hole 17c: Second guide groove 36 : First disc 36a: Through hole 36c: Guide groove 37: Second disc 37a: Through hole 37c: Guide groove

Claims (4)

Finely pulverized dry powder seaweed processed into powder by a conventionally known processing method to form fine powder seaweed particles, and then 15 to 25% by weight of the powdered seaweed particles is added to tap water or Addition and mixing to 75 to 85% by weight of electrolytic reduced water obtained by electrolyzing natural water, containing no chlorine, having an oxidation-reduction potential of 200 mV or less and containing active hydrogen, and mixing and stirring. Adjusting the mixed solution, adjusting the powder seaweed particles so that they are evenly dispersed in the electrolytic reduced water, and forming a flow of the powdered seaweed particles and the electrolytic reduced water;
In the first step, the flow material in which the powdered seaweed particles are dispersed in the electrolytically reduced water is introduced into an ultrafine particle making device and collided at a high pressure to crush the powdered seaweed particles to obtain the powdered seaweed particles. A second step of extracting active ingredients from the ultrafine powdered seaweed particles into the fluid by making the whole into ultrafine particles;
In the second step, the fluid obtained by extracting the active ingredient from the micronized powdered seaweed particles is dried by a drier to remove the water in the fluid by evaporating and removing the fluid. A third step of taking out as a bulk dry powder seaweed containing active ingredients;
A dry powder seaweed ultrafine particle processing method comprising: pulverizing the dry powder seaweed taken out in a lump form in the third step and processing the dried powder seaweed into a predetermined particle size. Dry powder seaweed processed into powder by a conventionally known processing method is finely pulverized to form fine powder seaweed particles. Thereafter, 15 to 25% by weight of the powder seaweed particles do not contain chlorine. The mixture is mixed and stirred in 75 to 85% by weight of any one of alkaline ionized water, mineral water or pure water, mixed and agitated, and the mixed liquid seaweed particles are mixed with the alkaline ionized water and mineral water. Alternatively, a first step of adjusting the powder so as to be evenly dispersed in any pure water and making it a flow of powdered seaweed particles and any one of the alkaline ionized water, mineral water or pure water,
In the first step, a flow material in which powder seaweed particles are dispersed in any one of the alkaline ionized water, mineral water, or pure water is introduced into an ultrafine particle device and collided at a high pressure, and the powder A second step of extracting active ingredients from the ultrafine powdered seaweed particles by crushing the seaweed particles and making the whole powdered seaweed particles into ultrafine particles;
In the second step, the fluid obtained by extracting the active ingredient from the micronized powdered seaweed particles is dried by a drier to remove the water in the fluid by evaporating and removing the fluid. A third step of taking out as a bulk dry powder seaweed containing active ingredients;
A dry powder seaweed ultrafine particle processing method comprising: pulverizing the dry powder seaweed taken out in a lump form in the third step and processing the dried powder seaweed into a predetermined particle size. Finely pulverized dry powder seaweed processed into powder by a conventionally known processing method to form fine powder seaweed particles, and then 15 to 25% by weight of the powdered seaweed particles is added to tap water or Addition and mixing to 75 to 85% by weight of electrolytic reduced water obtained by electrolyzing natural water, containing no chlorine, having an oxidation-reduction potential of 200 mV or less and containing active hydrogen, and mixing and stirring. Adjusting the mixed solution, adjusting the powder seaweed particles so that they are evenly dispersed in the electrolytic reduced water, and forming a flow of the powdered seaweed particles and the electrolytic reduced water;
In the first step, an ultrafine particle forming step of crushing the powdered seaweed particles by introducing a flow material in which the powdered seaweed particles are dispersed in the electrolytically reduced water into an ultrafine particle making device and colliding with high pressure. In order to reach the predetermined particle size, it is repeated several times, if necessary, by repeatedly adding 2 to 10% by weight of the electrolytically reduced water to the flow material, and the entire powdered seaweed particles are exceeded. A second step of extracting active ingredients from the ultrafine powdered seaweed particles into the fluid by micronization;
In the second step, the fluid obtained by extracting the active ingredient from the micronized powdered seaweed particles is dried by a drier to remove the water in the fluid by evaporating and removing the fluid. A third step of taking out as a bulk dry powder seaweed containing active ingredients;
A dry powder seaweed ultrafine particle processing method comprising: pulverizing the dry powder seaweed taken out in a lump form in the third step and processing the dried powder seaweed into a predetermined particle size. Dry powder seaweed processed into powder by a conventionally known processing method is finely pulverized to form fine powder seaweed particles. Thereafter, 15 to 25% by weight of the powder seaweed particles do not contain chlorine. The mixture is mixed and stirred in 75 to 85% by weight of any one of alkaline ionized water, mineral water or pure water, mixed and agitated, and the mixed liquid seaweed particles are mixed with the alkaline ionized water and mineral water. Alternatively, a first step of adjusting the powder so as to be evenly dispersed in any pure water and making it a flow of powdered seaweed particles and any one of the alkaline ionized water, mineral water or pure water,
In the first step, a flow material in which powder seaweed particles are dispersed in any one of the alkaline ionized water, mineral water, or pure water is introduced into an ultrafine particle device and collided at a high pressure, and the powder The ultrafine particle forming step for crushing the seaweed particles is repeated several times until reaching a predetermined particle size, and if necessary, the alkaline ionized water, mineral water or pure water 2 to 10 wt. A second step of extracting the active ingredient from the ultrafine powdered seaweed particles into the fluid by repetitively mixing and adding, and making the whole powdered seaweed particles ultrafine.
In the second step, the fluid obtained by extracting the active ingredient from the micronized powdered seaweed particles is dried by a drier to remove the water in the fluid by evaporating and removing the fluid. A third step of taking out as a bulk dry powder seaweed containing active ingredients;
A dry powder seaweed ultrafine particle processing method comprising: pulverizing the dry powder seaweed taken out in a lump form in the third step and processing the dried powder seaweed into a predetermined particle size.

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