JP5901005B2 - Paulownia charcoal supplement - Google Patents

Description

  The present invention relates to paulownia charcoal supplements and relates to paulownia charcoal supplements having an effect of improving various symptoms of the human body.

  Conventionally, various supplements that affect human symptoms are known. (For example, Patent Document 1) On the other hand, it has been generally known that some carbides absorb human toxins and promote excretion treatment.

Utility Model Registration No. 3149249

  Carbide produced by conventional carbonization equipment has a low specific surface area unless an activation process is performed, and thus has a low gas absorption rate. Therefore, deodorizing effects and methane gas absorption effects, which are one of the effects of supplements, can be expected. There wasn't. Moreover, since the carbide produced by the conventional carbonization apparatus breaks the natural structure of the raw material at the time of carbonization, the oil adsorption effect is low.

  The subject of this invention is providing the paulownia charcoal supplement which has the effect of improvement in the symptom of a human body using the paulownia charcoal produced with the carbonization apparatus of an oxygen-free atmosphere.

The paulownia charcoal supplement of the present invention utilizes the fact that the paulownia charcoal carbonized in a carbonization device that is carbonized in an oxygen-free atmosphere while stirring the carbonized material is excellent in oil adsorbing power and gas adsorbing power. It is a supplement.

The invention according to claim 1, salad oil adsorption amount, Ri 6 times to 11 times the Der own weight, BET specific surface area, in the manufacturing method of Kirisumi supplement with Kirisumi of 450~550m ² / g There,
The paulownia charcoal is paulownia charcoal carbonized in a carbonization device that is carbonized in an oxygen-free atmosphere while the paulownia is stirred, and the carbonization device is a kiln in which spiral wings and stirring wings are arranged. Have
The kiln rotates, and in the area inside the kiln, there is a drying unit that evaporates the water contained in the paulownia , and a carbonization unit in which the paulownia dried by the drying unit is thermally decomposed and carbonized. This is a method for producing a paulownia charcoal supplement characterized in that the area is set.

The invention according to claim 2 is the method for producing paulownia charcoal supplements according to claim 1, wherein the carbonization temperature of the carbonization apparatus is 400 ° C to 600 ° C.

The invention according to claim 3 is a paulownia charcoal formed by filling corn capsules with paulownia charcoal having a salad oil adsorption amount in the range of 6 to 11 times its own weight and a BET specific surface area of 450 to 550 m ² / g. A method for producing a supplement, wherein the paulownia charcoal is paulownia charcoal carbonized in a carbonization device that is carbonized in an oxygen-free atmosphere while stirring the paulownia, and the carbonization device has a spiral feather inside. And a kiln in which stirring blades are arranged, the kiln rotates, and in the area inside the kiln, a drying unit that evaporates moisture contained in the paulownia, and a paulownia that has been dried by the drying unit There is a method for producing a paulownia charcoal supplement you characterized in that carbide portion to be carbonized by thermal decomposition is set area.

The invention according to claim 4 is the method for producing a paulownia charcoal supplement according to claim 3 , wherein the carbonization temperature of the carbonization apparatus is 400 ° C to 600 ° C.

In the invention according to claim 5, the amount of salad oil adsorbed is in the range of 6 to 11 times its own weight, the BET specific surface area is 450 to 550 m ² / g paulownia charcoal, and the binder is mixed into a pellet form. A process for producing a processed pelleted paulownia charcoal supplement,
The paulownia charcoal is
Paulownia charcoal carbonized in a carbonizer that is carbonized in an oxygen-free atmosphere while being stirred.
The
The carbonization apparatus has a kiln in which a spiral blade and a stirring blade are arranged,
The kiln rotates,
In the area inside the kiln, a drying unit that evaporates the water contained in the paulownia,
Wherein in the drying section were dried paulownia is a manufacturing method of paulownia charcoal supplement carbide portion you characterized in that it is set the area to be carbonized thermolysis to.

The invention according to claim 6 is a method for producing a Kirisumi supplement of claim 5, wherein the carbonization temperature of the carbonization device is 400 ° C. to 600 ° C..

According to the method for producing paulownia charcoal supplements according to claims 1, 3 , and 5 , due to the paulownia charcoal supplement whose main component is paulownia charcoal, the salad oil adsorption amount is in the range of 6 to 11 times its own weight, It is possible to provide a method for producing paulownia charcoal supplements that can exhibit excellent improvement effects on various symptoms of the human body, gastrointestinal disorders, and the like.

Claim 2, according to the manufacturing method of Kirisumi supplement according to 4,6, with stirring, Oite carbide devices are carbonized in an oxygen-free atmosphere, carbonization temperature was 400 ° C. to 600 ° C. Kirisumi A method for producing a supplement can be provided.

  ADVANTAGE OF THE INVENTION According to this invention, the paulownia charcoal supplement which can exhibit the improvement effect excellent with respect to the various symptoms of a human body can be provided.

It is a perspective view of the paulownia charcoal supplement of the corn capsule form of this invention. It is a salad oil adsorption | suction test result of paulownia charcoal used for the paulownia charcoal supplement of this invention, paulownia-kun charcoal, and rice husk charcoal. It is a SEM photograph of paulownia charcoal used for the paulownia charcoal supplement of this invention, and is paulownia charcoal carbonized at 500 degreeC. It is a graph which shows the relationship between the carbonization temperature about the paulownia charcoal used for this invention, and a specific surface area in the case of the carbonization apparatus SUMIX, and the case of the carbonization apparatus MUFFLE. It is a figure which shows the measurement result of the carbonization temperature about the paulownia charcoal used for this invention, and a specific surface area and pore distribution. It is a perspective view of the pellet-shaped paulownia charcoal supplement of this invention. It is a block diagram of one example of the carbonization apparatus for carbonizing the paulownia charcoal of this invention. It is a graph which shows adsorption | suction of ethylene gas regarding the paulownia charcoal of this invention. It is a graph which shows adsorption | suction of ethylene gas by the paulownia charcoal of this invention, and other various adsorbents. It is a graph which shows adsorption | suction of ammonia gas regarding the paulownia charcoal of this invention. It is a graph which shows adsorption | suction of acetic acid gas regarding the paulownia charcoal of this invention.

The paulownia charcoal used in the paulownia charcoal supplement of the present invention is characterized by using paulownia charcoal carbonized in a carbonization apparatus that is carbonized in an oxygen-free atmosphere.
Here, the carbonization apparatus carbonized in an oxygen-free atmosphere may fix paulownia charcoal or may stir paulownia charcoal. In particular, when charcoal is stirred and carbonized in an oxygen-free atmosphere, it is excellent in terms of specific surface area.
As a carbonization apparatus to be used, any form may be used as long as the carbonized object (in this case, paulownia charcoal) is carbonized in an oxygen-free atmosphere.

  As an example of the carbonization apparatus, the block diagram of one example of the carbonization apparatus for carbonizing the paulownia charcoal of this invention was shown in FIG. As shown in FIG. 7, the carbonization apparatus (reduction carbonization processing apparatus) used in the present invention includes a rotating kiln 2 in which a spiral blade and a stirring blade 1 are disposed, and an interior of the one kiln 2. Combustion chamber 3 that stores the organic matter, etc., including the input waste, in an organic material etc. while indirectly heating in a reduced state in an oxygen-free atmosphere and supplies heat to the entire interior of one kiln 2, and the combustion chamber 3 A heating unit 4 such as a burner, a drying unit 2a having an area set inside the kiln 2 so as to evaporate water contained in the organic matter and the like introduced into the kiln 2 by indirect heating of the combustion chamber 3, and a drying unit A carbonized portion 2b having an area set inside the kiln 2 so as to be carbonized by indirectly heating and decomposing the organic matter dried by 2a.

Various characteristics of paulownia charcoal carbonized by the carbonization apparatus of FIG. 7 will be described below.
FIG. 2 is a result of a salad oil adsorption test of paulownia charcoal used in the paulownia charcoal supplement of the present invention, paulownia kun charcoal, and rice husk charcoal as a comparative example.
From FIG. 2, paulownia charcoal has a maximum amount of salad oil adsorbed at a carbonization temperature of 500 ° C., which is about 11 times its own weight, while the rice husk charcoal of the comparative example has its own weight at a carbonization temperature of 500 ° C. It stays 6 times. Here, paulownia charcoal has a salad oil adsorption amount of 6 to 11 times at a carbonization temperature of 300 ° C to 700 ° C. In practice, however, a carbonization temperature of 500 ° C. is used. This includes the purpose of excluding the generation of other harmful substances due to carbonization.
In addition, in FIG. 2, paulownia charcoal has shown the salad oil adsorption | suction of about 4 times its own weight.

  FIG. 3 is a SEM photograph of paulownia charcoal used in the paulownia charcoal supplement of the present invention, which is paulownia charcoal carbonized at 500 ° C. As shown in the photograph, holes are formed leaving the paulownia structure, and the holes of various sizes contribute to oil adsorption and gas adsorption. In particular, the effect of gas adsorption has the effect of preventing bad breath. The pores of 2 nm to 50 nm adsorb water vapor and other gases, and the pores of 50 nm or more adsorb oil, salad oil, and the like.

FIG. 4 is a graph showing the relationship between the carbonization temperature and the specific surface area of paulownia charcoal used in the present invention in the case of the carbonization apparatus SUMIX and in the case of the carbonization apparatus MUFFLE.
Moreover, FIG. 5 is a figure which shows the measurement result of the carbonization temperature about the paulownia charcoal used for this invention, and a specific surface area and pore distribution.
Here, the carbonization apparatus SUMIX is a carbonization apparatus shown in FIG. 7 that is carbonized in an oxygen-free atmosphere while being stirred, and the carbonization apparatus MUFFLE is a carbonization apparatus in a stationary state.
Regarding the specific surface area of paulownia charcoal, the correlation between the carbonization temperature and the specific surface area is reversed when carbonized while standing in the MUFFLE furnace and when carbonized while stirring with the carbonizer SUMIX.
Only when the paulownia is carbonized with SUMIX, it has the maximum specific surface area at a carbonization temperature of about 300-400 ° C. This is presumed to be due to the structure of paulownia as a raw material and thermal decomposition in anoxic and agitation with SUMIX.

In the case of SUMIX, paulownia charcoal has a specific surface area of 450 to 550 m ² / g at a carbonization temperature of 500 ° C., and has a specific surface area more than twice that of a sample carbonized at the same temperature in a MUFFLE furnace. Have. Here, the specific surface area was determined by the BET method.
In the case of SUMIX, compared to the batch-type MUFFLE furnace, it is considered that since heat is added in the kiln during carbonization, heat conduction is excellent, and high-performance carbide can be produced at a lower temperature. This is preferable both in terms of running cost and the yield of carbide to raw materials.

On the other hand, in paulownia charcoal, the carbides of SUMIX and MUFFLE furnaces show a completely opposite relationship between the carbonization temperature and the specific surface area. A sample carbonized at 300 ° C. by SUMIX has a specific surface area of 600 m ² / g or more. This is a numerical value that is thinner than activated carbon. Although the mechanism showing such properties is unknown at present, it is assumed that stirring and dry distillation gas influence the kiln as described above.

  In this example, the adsorption performance of ethylene gas, which is a neutral gas, was examined for paulownia charcoal and rice husk charcoal as a comparative example.

<Experimental procedure>
The adsorption performance was tested according to the following procedure.
(1) The target gas adjusted as described below is sealed in a 20 L tedlar bag, and left at room temperature (air conditioner control) for 1 hour or longer. (3) From the 20L Tedlar bag, measure the gas concentration in the 5L Tedlar bag using the gas detection tube at regular intervals immediately after the introduction of the target gas into the 5L Tedlar bag.

<Gas adjustment, etc.>
Gas adjustment method: Based on nitrogen-based ethylene gas standard gas (100 ppm).
Gas detector tube: GASTEC, ethylene detector tube (172L)
Sample carbide: rice husk charcoal (carbonization temperature 300-700 ° C), paulownia charcoal (300-700 ° C)
Remarks: Comparison with commercially available ethylene adsorbent “ethylene control”, granular palladium activated carbon “deodorized charcoal / vegetable room” (manufactured by Este Co., Ltd.), and Chinese charcoal.

<Experimental result>
The experimental results are shown in Tables 1 to 4 and FIGS.

  It was found that both “rice husk charcoal” and “paulownia charcoal” produced by the method of the present invention have good ethylene gas adsorption power. Samples carbonized at 500 to 700 ° C. (FIG. 9) for rice husk charcoal and 600 to 700 ° C. (FIG. 9) for paulownia charcoal gave the best results.

  In this example, the adsorption of ammonia gas, which is an alkaline gas, was experimented instead of the adsorption of ethylene gas.

  The experimental procedure was performed in the same manner as in Example 2.

<Gas adjustment, etc.>
Gas adjustment method: Ammonia water (10 w / v%) injected into 20L tedlar back Gas detector tube: GASTEC's ammonia detector tube (3La)
Sample carbide: rice husk charcoal (300-700 ° C), paulownia charcoal (300-700 ° C)
Remarks: Since it is difficult to match the ammonia gas concentrations for each experiment, the comparison was made based on the gas removal rate.
Gas removal rate [%]
= (1-gas concentration / blank concentration) × 100

<Experimental result>
The experimental results are shown in Tables 4 to 7 and FIG.

  From the above results, it was found that both rice husk charcoal and paulownia charcoal have excellent ammonia gas adsorption power. In particular, more preferable results were obtained when carbonized at 300 ° C and 400 ° C.

In this example, the adsorption of acetic acid gas, which is an acidic gas, was experimented instead of the adsorption of ethylene gas.
The experimental procedure was performed in the same manner as in Example 2.

<Gas adjustment, etc.>
Gas adjustment method: Acetic acid reagent (10 μL) in 20 L tedlar bag Gas detection tube: GASTEC, acetic acid gas detection tube (81, 81 L)
Sample carbide: rice husk charcoal (300-700 ° C), paulownia charcoal (300-700 ° C)
Remarks: Since it is difficult to match the acetic acid gas concentrations for each experiment, the comparison was made based on the gas removal rate. Moreover, the comparison with commercially available activated carbon (non-smel) was also performed.
Gas removal rate [%]
= (1-gas concentration / blank concentration) × 100

<Experimental result>
The experimental results are shown in Table 8, Table 9, and FIG.

In the acetic acid gas adsorption experiment that contributes to the bad odor, the above results revealed that paulownia charcoal has an excellent acetic acid gas adsorption power. “Tung charcoal” showed the best results when carbonized at 500 ° C. or less. Moreover, in the comparative experiment in paulownia charcoal, it turned out that all the samples carbonized at 300-700 degreeC have the adsorptive power which exceeds commercially available activated carbon (non-smel: trademark).
Such gas adsorption experiment results have the effect of absorbing methane gas when paulownia charcoal is used as a supplement.

  As described above, the effect of oil adsorption power of paulownia charcoal and the effects of various gas adsorption powers of paulownia charcoal appear as effects of taking paulownia charcoal supplements. In particular, the effect of paulownia charcoal gas adsorption contributes to the prevention of bad breath.

  The effect of the paulownia charcoal supplement of the present invention will be described below.

(Example 1)
According to the carbonization conditions described in the embodiment, the produced paulownia charcoal was packed in a corn capsule, a paulownia charcoal supplement was made as a trial, and the effect was verified.

<Experimental sample>
FIG. 1 is a perspective view of the corn capsule form paulownia charcoal supplement of the present invention. In FIG. 1, the paulownia charcoal supplement is formed by sealing the paulownia charcoal 100 in a corn capsule 400.
(Conditions for carbonization)
Here, the carbonization conditions of the paulownia charcoal 100 are prepared under the carbonization conditions of stirring, carbonization in an oxygen-free atmosphere, and a carbonization temperature of 500 ° C. (For example, using the apparatus of FIG. 7)

<Experiment method>
The prototype paulownia charcoal supplement was taken by a total of 15 men, 8 men and 7 women, for 10 days, and the effect was examined. The dosage method was 3 times a day, 1 capsule at a time.

<Experimental result>
Table 10 shows the symptom improving effect by taking the paulownia charcoal supplement of the present invention.
Table 11 summarizes the feelings of the subjects who took paulownia charcoal supplements.
From Tables 10 and 11, it was confirmed that the paulownia charcoal supplement of the present invention had an improvement effect on the symptoms of the human body.

(Example 2)
FIG. 6 is a perspective view of the pelletized paulownia charcoal supplement of the present invention.
In FIG. 6, a paulownia charcoal supplement 501 is formed by mixing paulownia charcoal 101 with a binder 600 and pressurizing it to form a pellet.

(Conditions for carbonization)
Here, the carbonization conditions of the paulownia charcoal 101 are prepared under the carbonization conditions of stirring, carbonization in an oxygen-free atmosphere, and a carbonization temperature of 500 ° C. (For example, using the apparatus of FIG. 7)

<Experiment method>
The prototype paulownia charcoal supplement was taken by a total of 15 men, 8 men and 7 women, for 10 days, and the effect was examined. The dosage method was 3 times a day, 1 capsule at a time.

<Experimental result>
The effects corresponding to Tables 10 and 11 above were obtained.

  The paulownia charcoal supplement of the present invention can improve symptoms by being taken by a patient and can be used for medical purposes. In addition, the oil or gas adsorbent described in this embodiment can be used by being stored in an oil-permeable or gas-permeable packaging, container, pack, capsule, or the like. Furthermore, paulownia charcoal simple substance can also be used.

  Also, paulownia charcoal can be used by being folded into a sheet.

DESCRIPTION OF SYMBOLS 2 ... Kiln 2a Drying part 2b Carbonization part 2d Heat storage part 2c Internal space 2in Inlet 2out Outlet 3 ... Combustion chamber 3a ... Exhaust pipe 4 ... Heat source 5 ... Piping part 6 ... Cooling part 7 ... Deodorizing part 8 ... Dry distillation gas recovery part 9 ... Auxiliary heating source 10 ... Steam smoke path 11 ... Oilification section 12 ... Water distribution pipe 13 ... Fan 14 ... Hopper 15 ... Raw material supply pipe 16 ... Supply screw 17 ... Second discharge pipe 18 ... Cooling device 19 ... Connection pipe (downstream side) Exhaust pipe)
19a Downstream exhaust pipe upper pipe
19b Downstream exhaust pipe
20 ... Conveying screw 21 ... Conveying screw 22 ... Steam vent pipe (upstream exhaust gas pipe)
22a Upper side exhaust pipe upper pipe
22b Upstream exhaust pipe lower pipe
23 Chimney part 24 Circulating pipe 25 Gas vent pipe 30 Connection part 60 Collection part P Input material Q Carbonized material 100, 101 Paulownia charcoal 200 Capsule lid part 300 Corn capsule container part 400 Corn capsule 500, 501 Paulownia charcoal supplement 600 binder

Claims (6)

Salad oil adsorption amount, Ri 6 times to 11 times the Der own weight, BET specific surface area, a method for producing a Kirisumi supplement with Kirisumi of 450~550m ² / g,
The charcoal is
The paulownia charcoal is carbonized in a carbonization device that is carbonized in an oxygen-free atmosphere while being stirred,
The carbonization apparatus has a kiln in which a spiral blade and a stirring blade are arranged,
The kiln rotates,
In the area inside the kiln, a drying unit that evaporates the water contained in the paulownia ,
A method for producing a paulownia charcoal supplement , characterized in that an area is set with a carbonized portion in which the paulownia dried by the drying section is thermally decomposed and carbonized. The carbonization temperature of the said carbonization apparatus is 400 to 600 degreeC, The manufacturing method of the paulownia charcoal supplement of Claim 1 characterized by the above-mentioned. Salad oil adsorption amount is in the range of 6 to 11 times its own weight, BET specific surface area is 450 to 550m ² / G of paulownia charcoal supplements formed by filling corn capsules in corn capsules,
The paulownia charcoal is
Paulownia charcoal carbonized in a carbonization device that is carbonized in an oxygen-free atmosphere while being stirred,
  The carbonization apparatus has a kiln in which a spiral blade and a stirring blade are arranged,
The kiln rotates,
In the area inside the kiln, a drying unit that evaporates the water contained in the paulownia,
A method for producing a paulownia charcoal supplement, characterized in that an area is set with a carbonized portion in which the paulownia dried by the drying section is thermally decomposed and carbonized. The carbonization temperature of the said carbonization apparatus is 400 to 600 degreeC, The manufacturing method of the paulownia charcoal supplement of Claim 3 characterized by the above-mentioned . Salad oil adsorption amount is in the range of 6 to 11 times its own weight, BET specific surface area is 450 to 550 m ² / g paulownia charcoal and binder is mixed and processed into pellets, pelletized paulownia charcoal supplement A manufacturing method of
The paulownia charcoal is
Paulownia charcoal carbonized in a carbonizer that is carbonized in an oxygen-free atmosphere while being stirred.
The
The carbonization apparatus has a kiln in which a spiral blade and a stirring blade are arranged,
The kiln rotates,
In the area inside the kiln, a drying unit that evaporates the water contained in the paulownia,
A method for producing a paulownia charcoal supplement, characterized in that an area is set with a carbonized portion in which the paulownia dried by the drying section is thermally decomposed and carbonized . The carbonization temperature of the said carbonization apparatus is 400 to 600 degreeC , The manufacturing method of the paulownia charcoal supplement of Claim 5 characterized by the above-mentioned.

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