JPH119267A - Capsule packed with useful bacterial spore for promoting decomposition of nutrient in organism treatment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain the subject capsule for making a useful bacterium for decomposing a nutrient take preference in the decomposition of a nutrient by organism treatment, by packing a soluble capsule with both a useful bacterial spore- containing material and a silica eluting material. SOLUTION: A soluble capsule 1 is packed with a material containing a spore of a useful bacterium which is an aerobic bacterium for forming a spore and with a material for eluting silica 3. The capsule can be packed with a dried nutrient 5 obtained by making a nutrient into a dried state and with a material for eluting magnesium 4. The objective capsule for supplying a useful bacterium suitable for decomposing a nutrient in the circulation and filtration of water and garbage treatment, etc., and minerals and for readily germinating the useful bacterium.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention aims at supplying useful bacteria and minerals necessary for nutrient decomposition in circulating filtration of water for decomposing nutrients in biological treatment, garbage treatment, and the like. The present invention relates to capsules that germinate in germination

[0002]

2. Description of the Related Art For the purpose of decomposing nutrients by biological treatment,
Various circulation filters and garbage disposers for water or bath water have been proposed and put into practical use. However, in biological treatment, although it is said that useful bacteria are implanted in filter media and the like to decompose nutrients, the present inventor conducted a culture experiment on bacteria attached to these filter media and the like. Is rare in many cases, and on the contrary, some rot bacteria, which are called malignant bacteria, are growing, and it has been found that there are few useful bacteria related to biological treatment.

[0003]

DISCLOSURE OF THE INVENTION The present invention was devised in order to eliminate the disadvantages of the present invention. In degrading nutrients by biological treatment, priority is given to useful bacteria that can degrade nutrients by being introduced. It is intended to suppress various spoilage bacteria called malignant bacteria.

[0004]

Therefore, the present inventor has conducted research on useful bacterial spores contained in capsule fillings. The useful bacteria referred to in the present invention are bacteria (Bacillus) which are aerobic and form spores. The bacteria germinate, grow, grow nutrients, water, oxygen,
Requires minerals. If these conditions are met,
It has the ability to break down and prioritize nutrients and kill other bacteria such as cocci and staphylococci. Also,
When it becomes oligotrophic, it spores and germinates with nutrient supply.

Useful bacteria require at least silica and magnesium as minerals. Silica is an important substance constituting the cell membrane, cell fluid, and spore membrane of useful bacteria. If the amount of silica is insufficient, the useful bacteria cannot grow. Magnesium also has the effect of shortening the growth cycle of useful bacteria.

[0006] Then, as a result of examining the content of useful bacterial spores to be filled in the capsule, it was concluded that it is most preferable to use a crushed or crushed product of the natural ore cristobalite.

Cristobalite is mainly composed of silica,
It is a porous mineral with a very high porous morphology.
Moreover, the void contains a myriad of useful bacterial spores, and the spores can be brought to a state just before germination by heating with water. When more nutrients are supplied, they germinate immediately to break down the nutrients. It also has the property of sporulating again with the appearance of an oligotrophic state in the presence of minerals necessary for its sporulation.

Next, at least the main positions of sedimentary rocks containing cristobalite (aerobic and spore-forming bacteria) containing useful bacterial spores, which are currently confirmed, will be described.

[0009] Black gray hard shale and mudstone are distributed in the northeastern part of Shimokita Peninsula in Aomori Prefecture and around Uranozawa, Higashimura, Shimokita-gun. Cristobalite and zeolite are found in the hard shale and mudstone.

Cristobalite containing zeolite is also found in hard mudstone near Yazawa, Hiraka-gun, Akita Prefecture or near Gojome, Akita-gun, Akita Prefecture. In these cristobalites, the presence of a large amount of useful bacterial spores was confirmed at least in the voids.

(Experimental example) Confirmation of useful bacteria of cristobalite a The surface of cristobalite was observed with an electron microscope scanning image, and it was confirmed that a large amount of spores of useful bacteria were present in the voids. b Cristobalite was finely pulverized, 1 g thereof was taken in 10 ml of a liquid medium (glucose 0.8%, brain heart infusion 0.8%, salt 0.6%) in a scale, and sprinkled on it. Cultured for days.
As a result, the appearance of innumerable sporulated colonies of useful bacteria was confirmed.

Furthermore, the useful bacterial spore-containing material to be filled into capsules, spores useful bacterial high concentration spores sludge (useful bacteria obtained by growing the useful bacteria in sewage treatment plants or the like at least 10 ⁶ / ml than about (Preferably containing) or dried or fermented and dried.

[0013] In the case of dried sludge, since minerals necessary for the growth and resporulation of useful bacterial spores are lacking, natural minerals containing at least silica and magnesium may be used in combination.

(Experimental Example) Confirmation of Useful Bacteria in Dry Sludge A drawn sludge from a urine treatment plant treated with useful bacteria was dehydrated and naturally dried to obtain dried sludge.
This dried sludge is pulverized, 1 g thereof is fractionated and 1000 m
1 g of pure water, sprayed on an agar medium containing soluble starch and protein, and cultured at 31 ° C. for 3 days to germinate. As a result, it was confirmed that useful bacterial spores were present in the sludge.

[0015]

Next, an example of a capsule production method for filling a useful bacterial spore content will be described.

It is preferable that the soluble capsule is nutrient-produced by melting, and easily germinates useful bacterial spores in an oligotrophic state.

An outline of an example of a method for producing a soluble capsule is as follows. Those that are removed as unnecessary portions when processing meat or skin include skin, bone, cartilage, tendons, and the like. These contain a large amount of collagen, a kind of protein, which is extracted by hot water and coagulated, and is called gelatin or gelatin. In the case of using skins and tendons as raw materials, remove proteins other than collagen by immersion, and in the case of bones, crush and defat the bones, respectively, remove minerals with thin hydrochloric acid and simultaneously neutralize lime, then Wash thoroughly with water. When this water is added and heated to 70 ° C to 80 ° C, a thick glue liquid is obtained. This is filtered and the filtrate is solidified at about 15 ° C. Furthermore, capsules are formed by evaporating and solidifying the molded product having an appropriate size at 20 ° C to 30 ° C. Glue and gelatin are not so different in composition, but glue is crude, whereas gelatin is a pure material obtained by purifying fresh raw materials by a clean method.

Also, a small amount of water is added to flour and kneaded,
The clumps are called wet gluten, but when kneaded in a large amount of water, the starch is dispersed and removed in the water, leaving a sticky gum-like mass. This is called gluten. A capsule may be prepared by evaporating and solidifying the molded product.

The soluble and nutritious capsule is not merely for encapsulating the contents containing useful bacterial spores, but is dissolved upon contact with water and easily becomes a nutrient for useful bacteria.

For example, when only useful bacterial spores are put into oligotrophic water, they do not germinate. However, by encapsulating them in a soluble and nutritive capsule, nutrients can be obtained from the useful bacterial spore-containing material, and the nutrients can be easily obtained. Germinate.

Next, an example of the material of the porous capsule will be described. By using a porous material for the capsule, the useful bacteria play a role as a biological carrier after germination, and the contact area and the implantation area of the useful bacteria are expanded.
It significantly promotes nutrient degradation.

The most preferred porous material for making capsules is porous and adsorbent charcoal. Filling or implantation of useful bacterial spores on charcoal is based on multiplying the property of adsorbing organic matter (nutrients). Nutrients can be stably and preferentially fed to useful bacteria and activated.

Further, a porous volcanic pumice having silica as a main component may be used. Filling the volcanic pumice with the useful bacterial spore-containing material can easily obtain the necessary mineral silica for the useful bacterial spore.

Further, ceramics and the like can be used, but their adsorptivity is poor. However, those that elute silica or magnesium into eluting minerals such as ceramics are not merely for inclusion of useful bacterial spores, and useful bacteria can obtain necessary minerals and are easily activated.

As an example, a method for producing a porous capsule will be described. A hole for filling the charcoal with the useful bacterial spore-containing material is pierced to the center of the charcoal with a drill or the like, and after filling the useful bacterial spore, the hole is plugged. Moreover, the hole drilled in the charcoal may be penetrated. In the method of filling useful bacteria when penetrated, first, one of the holes is closed with a stopper, and the other hole is filled with a substance containing useful bacterial spores, and then the hole is closed.

The plug for closing the hole is preferably urethane, sponge, ceramic, or the like, for the purpose of germinating useful bacteria easily from the plug. Natural minerals or molded products which are porous and supply necessary minerals are preferably used. Is more effective. Even after the useful bacteria are filled, the useful bacteria contained by the porous structure of the charcoal body will easily germinate even if the plug is sealed.

Next, the dry nutrients contained in a soluble, porous or permeable capsule and the preparation method are described.

[0028] In order to enable the nutrients to be easily obtained by contacting with moisture, the useful bacterial spore-containing material contained in the soluble, porous or permeable capsule can be obtained in the same manner as the soluble and nutritive capsule. It is desirable to include nutrients together.

The method of preparing dry nutrients to be filled is to prepare meat and fish by drying in the sun. In addition, a dried product such as coconut or tofu may be filled. These dry nutrients are nutrients of useful bacteria easily upon contact with water.

[0030]

As described in detail above, the capsule of the present invention causes the generation and prioritization of useful bacteria by being injected, and activates the useful bacteria in the presence of the necessary minerals to remarkably promote the degradation of nutrients. .

[Brief description of the drawings]

FIG. 1 is a front view showing an example of a soluble capsule according to the present invention.

FIG. 2 is a cross-sectional view of FIG. 1A-A showing an example of a soluble capsule according to the present invention.

FIG. 3 is a front view showing an example of a capsule that is soluble and nutritious according to the present invention.

FIG. 4 is a cross-sectional view of FIG. 3B-B showing an example of a soluble and nutritive capsule according to the present invention.

FIG. 5 is a front view showing an example of a capsule made of a porous material according to the present invention.

FIG. 6 is a cross-sectional view of FIG. 5C-C showing an example of a capsule made of a porous material according to the present invention.

FIG. 7 is a cross-sectional view of FIG. 5C-C showing another example of a capsule made of a porous material according to the present invention.

[Explanation of symbols]

 1 is a soluble capsule 2 is a substance containing useful bacterial spores 3 is silica 4 is magnesium 5 is a dry nutrient 6 is a soluble and nutritive capsule 7 is a capsule made of a porous material 8 is a plug

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁶ Identification code FI C02F 3/00 ZAB B09B 3/00 ZABD

Claims (17)

[Claims] 1. A capsule filled with useful bacterial spores that promote nutrient degradation in biological treatment, characterized in that a soluble capsule is filled with a material containing useful bacterial spores and a material eluted with silica. 2. A capsule filled with useful bacterial spores for promoting nutrient decomposition in biological treatment according to claim 1, wherein the soluble capsule is filled with the nutrient in a dry state. 3. A capsule filled with useful bacterial spores, which promotes nutrient degradation in biological treatment, characterized in that a soluble capsule is filled with a material containing useful bacterial spores and a material that elutes magnesium. 4. A capsule filled with useful bacterial spores for promoting nutrient degradation in biological treatment according to claim 3, wherein the soluble capsule is filled with the nutrient in a dry state. 5. A capsule filled with useful bacterial spores, which promotes nutrient degradation in biological treatment, characterized in that the capsule is filled with soluble bacterial spores. 6. A capsule filled with useful bacterial spores for promoting nutrient degradation in biological treatment according to claim 5, wherein a capsule capable of dissolving at least silica is filled together with the capsule, which is soluble and nutritive. . 7. A capsule filled with useful bacterial spores for promoting nutrient degradation in biological treatment according to claim 5, characterized in that a capsule capable of eluting at least magnesium is filled together with the soluble nutritive capsule. . 8. A capsule filled with useful bacterial spores that promote nutrient degradation in biological treatment, wherein the capsule filled with the useful bacterial spore-containing material is made of a porous material. 9. The useful bacterial spore that promotes nutrient degradation in biological treatment according to claim 8, wherein a capsule made of a porous material is filled together with a material that elutes at least silica. Filled capsules. 10. A capsule made of a porous material,
The capsule filled with useful bacterial spores for promoting nutrient degradation in biological treatment according to claim 8, characterized in that the capsule is filled with a material that elutes at least magnesium. 11. A useful bacterial spore that promotes nutrient degradation in biological treatment according to claim 8, wherein at least a part of the capsule made of a porous material is made of a material that elutes silica. Filled capsules. 12. A useful bacterial spore which promotes the degradation of nutrients in biological treatment according to claim 8, wherein a part of the capsule made of a porous material is made of a material that elutes at least magnesium. Filled capsules. 13. The capsule filled with useful bacterial spores which promote nutrient decomposition in biological treatment according to claim 8, wherein the nutrient is dried and filled together. 14. A capsule filled with useful bacterial spores, which promotes the degradation of nutrients in biological treatment, characterized in that the capsule is filled with the useful bacterial spore-containing material. 15. A capsule filled with useful bacterial spores which promote nutrient degradation in biological treatment according to claim 14, wherein the capsule having permeability is filled with at least a material eluted with silica. 16. A capsule filled with useful bacterial spores for promoting nutrient degradation in biological treatment according to claim 14, wherein the capsule having permeability is filled with at least a material eluted with magnesium. 17. The capsule filled with useful bacterial spores for promoting nutrient degradation in biological treatment according to claim 14, wherein the nutrient is filled together with a dry bear.