JP2009101331A - Method for carrying metal on wood biomass, metal carrier of wood biomass, method for producing silver ion water, method for producing sodium ion water - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for carrying a metal on a wood biomass, which enhances effective utilization of the wood biomass as a natural resource by imparting the wood biomass a new function. <P>SOLUTION: The method comprises conducting a first plasma irradiating process irradiating an oxygen plasma to the wood biomass, and a second plasma irradiating process irradiating a plasma containing a metal element, whereby the metal element of the plasma irradiated in the second plasma irradiating process is carried by the wood biomass. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

The present invention relates to a metal loading method on woody biomass using low-temperature plasma, and a metal carrier of woody biomass obtained by this metal loading method.
Moreover, this invention relates to the method of manufacturing silver ion water using the silver support | carrier of woody biomass.
Moreover, this invention relates to the method of manufacturing sodium ion water using the sodium support | carrier of woody biomass.

Along with the development of science, soil contamination due to dioxins and heavy metals is regarded as a problem (for example, see Non-Patent Document 1).
Moreover, in the chlorine sterilization process of the water purification process, harmful trihalomethane is generated by reaction with organic substances in the raw water.
As measures against this trihalomethane, development of a new sterilization method replacing chlorine is expected (for example, see Non-Patent Document 2 and Non-Patent Document 3).

By the way, today, the reuse of wood waste and the use of wood biomass are being reviewed.
Conventionally, when using woody biomass, the main components of lignin, hemicellulose, and cellulose are completely separated, and then the separated components are used.
Each component is separated by extraction with heat, an alkali or an organic solvent, hydrolysis with an acid, a combination thereof, and the like.
However, in addition to causing damage to the components, many processing steps are required and the operation is complicated, resulting in an increase in manufacturing cost (see, for example, Non-Patent Document 4 and Non-Patent Document 5). ).

In addition, as a method of treating wood flour after the lignin component has been completely removed, a graft polymerization method has been conventionally employed, and inorganic substances, plastics, and the like have been chemically combined with wood flour (for example, non-patent literature) 6).
Since such a graft polymerization method is mostly a wet method using a solvent, the number of processing steps is increased, the operation is complicated, and the running cost of the processing is high.

On the other hand, as a dry method, a graft polymerization method in which various functional groups are introduced as monomers into a base polymer such as polyethylene, polypropylene, and cellulose using gamma radiation has attracted attention (for example, Non-Patent Document 7 and Non-Patent Document 7). Reference 8).
However, there is still considerable resistance to the use of radiation because the awareness-raising that a trace amount of radiation exposure is not dangerous to the human body has not yet permeated. Therefore, the use of radiation has been avoided.

Kim, H.K. et al., “Dioxins in Drinking Water Treatment Process”, OrganohalogenCompounds, 51, p.135-138, (2001) Bellar, T.A. et al., “The Occurrence of Organohalidesin Chlorinated Drinking Waters”, J. American Water Works Association, 66, p.703-706, (1974) Gray, N.F., “Drinking Water Quality”, John Wiley & Sons, p. 315, (1994) Nakamura et al., “Resinification of Woody Lignin and Its Characteristics on safety and Biodegradation”, J. Chem. Eng. Jpn., 34, p.1309-1312, (2001) Minowa et al., “Decomposition of Cellulose and Glucose in Hot-Compressed Water under Catalyst-Free Conditions”, J. Chem. Eng. Jpn., 31, p. 131-134, (1998) Hamada K., “Practical Use of Wood Materials by Graft Polymerization (Part1) Graft Polymerization of Methyl Methacrylate onto Wood Using Tetravalent Cerium as Initiator”, The Research Report of Kochi Prefecture Industrial Technology Center, 33, p. 15-19, (2002 ) Wada et al, “Control of Biodegradability of Poly (3-Hydroxybutyric Acid) Film with Grafting Acrylic Acid and Thermal Remolding”, J. Appl. Polym. Sci., 101, p.3856-3861, (2006) Furusawa et al., “Structural and Kinetic Modification of Aquenous Hydroxypropylmethylcellose (HPMC) Induced by Electron Beam Irradiation”, PhysicaA, 353, p.9-20, (2005)

As described above, countermeasures against soil contamination and development of new sterilization methods that replace chlorine are required.
In addition, effective utilization of woody biomass as a resource is required.

In order to solve the above-described problems, in the present invention, a method for supporting metal on woody biomass, which provides a new function to woody biomass and promotes effective use as resources, and metal of woody biomass A carrier is provided.
Moreover, the manufacturing method of silver ion water and the manufacturing method of sodium ion water using the metal support | carrier of woody biomass are provided.

  The metal loading method to the woody biomass of the present invention includes performing a first plasma irradiation process of irradiating oxygen biomass with a woody biomass and a second plasma irradiation process of irradiating a plasma containing a metal element. The woody biomass carries the metal element of the plasma irradiated in the second plasma irradiation step.

That is, in the metal supporting method of the present invention, first, oxygen plasma is irradiated as a first plasma irradiation step with wood components being not separated from the woody biomass.
In the first plasma irradiation step, the treatment is performed in a dry state, and the lignin component is oxidized by the strong oxidizing power of oxygen plasma (ozone). As a result, the woody biomass becomes porous and functional groups rich in oxygen are easily modified on the surface of lignin. Similarly, the functional group of the cellulose component is easily modified on the surface.

  In the metal carrying method of the present invention, next, as a second plasma irradiation step, plasma containing a metal element such as silver, sodium or titanium oxide is irradiated. Thereby, the substance (a metal, a metal compound, etc.) containing a metal element is carry | supported by the porous woody biomass.

The first plasma irradiation step and the second plasma irradiation step according to the method of the present invention can be performed by irradiating glow discharge plasma in the wavelength range of visible light, and perform such plasma irradiation. Therefore, it is possible to completely eliminate the risk of exposure to the human body and residual.
In addition, the strong electron energy enables graft polymerization in a dry state.

Examples of the woody biomass used in the present invention include, for example, wood chips, waste wood and thinned wood processed as waste, wood powder containing lignin, and drip coffee. Examples include debris.
Preferably, the woody biomass is reduced to a powder or a few mm or less so that the plasma irradiation step can be easily performed and the plasma can be efficiently processed.
Such woody biomass is an organic substance that can be obtained at low cost, and is decomposed in a natural environment. Therefore, when used as a bulk material, it is particularly effective in terms of cost and environmental load.

In the second plasma irradiation step, when silver-containing plasma is generated using silver nitrate, a silver support of woody biomass can be produced.
The silver carrier thus obtained can be used as a raw material for silver ion water.

In the second plasma irradiation step, when sodium-containing plasma is generated using sodium amide, a wood biomass sodium support can be produced.
The sodium carrier thus obtained can be used as a raw material for sodium ion water. Further, halogen such as chlorine can be removed by using a strong reduction reaction of sodium, and it can be used for purification of soil contamination, for example.

In the second plasma irradiation step, when titanium tetrachloride is used to generate a plasma containing titanium oxide, a wood biomass titanium oxide carrier can be produced.
The titanium oxide support thus obtained has a function as a photocatalyst, and generates strong oxidizing power on the surface when irradiated with ultraviolet rays, so that organic compounds and the like can be decomposed. Thereby, it becomes possible to apply to purification of water and air, antifouling materials, antibacterial materials, deodorizing materials, and the like.

The metal carrier of the woody biomass of the present invention is such that a substance containing a metal element is carried on the woody biomass.
The metal carrier of the woody biomass of the present invention can be obtained by the above-described metal loading method on the woody biomass of the present invention.

  Further, the method for producing silver ion water of the present invention uses a silver support of woody biomass produced by the method of metal loading on woody biomass according to the present invention, puts this silver carrier in water, and silver ions in water. It is to be eluted.

  Further, the method for producing sodium ion water of the present invention uses a sodium support of woody biomass produced by the method of metal loading on woody biomass according to the present invention. It is to be eluted.

  According to the above-described metal loading method on woody biomass of the present invention, a new function corresponding to the metal element carried on woody biomass can be provided.

The metal support of the woody biomass of the present invention has a new function corresponding to this metal element depending on the metal element carried on the woody biomass.
For example, it can be used as a raw material for ionic water to produce high-concentration ionic water, and can be applied to antibacterial materials, deodorizing materials, purification materials, and the like.
Therefore, according to the present invention, it is possible to promote effective utilization of woody biomass as a resource.

According to the method for producing silver ion water of the present invention, a porous material is obtained by putting a silver support of woody biomass produced by the metal loading method on the woody biomass according to the present invention into water and eluting silver ions into water. Since woody biomass carries a large amount of silver on a large surface area, it becomes possible to produce high-concentration silver ion water.
Further, since silver ions can be gradually eluted from the silver carrier, silver ion water can be produced repeatedly from the silver carrier.
Therefore, since the persistence and retention durability as silver ion water are excellent, it becomes possible to produce silver ion water with a relatively small amount of silver carrier, and it is easy to transport the raw material of silver ion water, etc. .

According to the method for producing sodium ion water of the present invention, the sodium support of the woody biomass produced by the metal loading method on the woody biomass according to the present invention is put into water, and the sodium ions are eluted into the water, thereby making the porous material porous. Since woody biomass carries a large amount of sodium on a large surface area, it is possible to produce sodium ion water having a high concentration.
Further, since sodium ions can be gradually eluted from the sodium carrier, sodium ion water can be produced repeatedly from the sodium carrier.
Therefore, since the persistence and retention durability as sodium ion water are excellent, it becomes possible to produce sodium ion water with a relatively small amount of sodium carrier, and it is easy to transport the raw material of sodium ion water, etc. .

A specific embodiment of the present invention will be described.
In the present invention, the metal element is supported on the woody biomass only in the state of a metal compound (including an alloy) or a metal compound such as a metal oxide.

In the method for supporting metal on the woody biomass of the present invention, first, oxygen plasma is generated to perform the first plasma irradiation step, and then plasma containing the metal element to be supported is generated to generate the second plasma. An irradiation process is performed.
The first plasma irradiation step and the second plasma irradiation step can be performed using a plasma reaction tube furnace.
And these 1st plasma irradiation processes and 2nd plasma irradiation processes can be performed using the same plasma reaction tube furnace by changing source gas.

The schematic block diagram of one form of the manufacturing apparatus for manufacturing the metal carrier of the woody biomass of this invention is shown in FIG.
This apparatus uses the plasma reaction tube furnace 5 to perform the first plasma irradiation step and the second plasma irradiation step according to the method of the present invention.
The plasma reaction tube furnace 5 comprises a reaction tube for generating plasma, and an electromagnetic induction coil 4 is wound around the reaction tube. The reaction tube is composed of, for example, a quartz tube. The electromagnetic induction coil 4 is constituted by, for example, a copper pipe.
The plasma reaction tube furnace 5 is an external induction type low-pressure low-temperature plasma furnace. For this reason, there is no electrode inside the furnace 5, and stable precursor plasma can be obtained uniformly over a large volume, and three-dimensional plasma irradiation can be performed.
An oxygen gas cylinder 6 for generating oxygen plasma is connected to the plasma reaction tube furnace 5.
This apparatus includes a high frequency power source 3 that supplies a high frequency for performing high frequency heating. High-frequency induction heating can be performed on the plasma reaction tube furnace 5 by supplying high-frequency power from the high-frequency power source 3 to the copper pipe of the electromagnetic induction coil 4.
The apparatus includes a water tank 1 and a pumping pump 2 for supplying cooling water to be fed into the copper pipe of the high-frequency power source 3 and the electromagnetic induction coil 4.
A liquid nitrogen trap 7 and a trap 8 containing slaked lime are connected to the rear stage of the plasma reaction tube furnace 5 as a trap part for capturing dangerous reaction exhaust gas.
At the subsequent stage, a Pirani vacuum gauge 9 and a vacuum pump 10 for measuring the degree of vacuum are provided as a vacuum exhaust device. For example, an oil rotary pump is used as the vacuum pump 10. By evacuating the inside of the plasma reaction tube furnace 5 with the vacuum pump 10, plasma can be generated at a low temperature.
Furthermore, in order to process the exhaust gas from the vacuum pump 10, an electric suction machine 11 that performs forced suction and a scrubber (exhaust gas cleaning device) 12 are provided in the subsequent stage.

The manufacturing apparatus for manufacturing the metal carrier of the present invention is not limited to the apparatus configuration shown in FIG.
The apparatus configuration shown in FIG. 1 is experimental and suitable for producing a relatively small amount.
What is necessary is just to set it as the apparatus structure suitable for mass production, when manufacturing the metal support | carrier of woody biomass in large quantities.

By using the woody biomass silver carrier according to the present invention, high-concentration silver ion water can be obtained with a small power of about 300 W.
In addition, since it has excellent persistence and retention durability as silver ion water, it becomes possible to produce silver ion water with a relatively small amount of silver carrier, and it is easy to transport the raw material of silver ion water, etc. .

In silver ion water, hydroxyl radicals (active oxygen) and hydrogen radicals are generated locally and instantaneously, and the bactericidal effect is exhibited.
Silver ion water can be used for purification of water purification plants, hospitals, hot springs, swimming pools, park fountains, cooling towers, factory / household wastewater, etc., regardless of the installation location.

Silver nitrate is suitable as a silver raw material for producing a silver support of woody biomass, but other raw materials may be used.
In the case of silver nitrate, gas plasma can be generated by melting and vaporizing from a solid state.

  When the sodium support of woody biomass according to the present invention is sprayed on contaminated soil such as heavy metals and dioxins, the organic compound containing chlorine and PCB can be dechlorinated in a natural environment by the strong reduction reaction.

By using the woody biomass sodium support according to the present invention, a high concentration of sodium ion water is obtained.
In addition, since it has excellent persistence and retention durability as sodium ion water, it becomes possible to produce sodium ion water with a relatively small amount of sodium carrier, and it is easy to transport the raw material of sodium ion water, etc. .

Sodium amide is suitable as a sodium raw material for producing a wood biomass sodium carrier, but other raw materials may be used.
In the case of sodium amide, gas plasma can be generated by melting and vaporizing from a solid state.

The titanium oxide support of woody biomass according to the present invention has a function as a photocatalyst, and generates strong oxidizing power on the surface when irradiated with ultraviolet rays, so that it can decompose organic compounds and the like. Thereby, for example, harmful substances such as dioxin, carcinogenic substances such as trihalomethane, and bacteria can be decomposed.
Therefore, it can be applied to water and air purification, anti-contamination materials, antibacterial materials, deodorizing materials, and the like.

Titanium tetrachloride is suitable as a raw material for titanium when producing a titanium oxide carrier for woody biomass, but other raw materials may be used.
In the case of titanium tetrachloride, gas plasma can be generated by vaporizing under reduced pressure from a liquid state.

It is also possible to carry other substances (metal elements, metal compounds, etc.) on the woody biomass.
The present invention can be applied to any substance containing a metal element that can be converted into gas plasma.

Even when the metal elements other than silver, sodium, and titanium described above are supported on the woody biomass, it is considered that the metal support of the woody biomass has characteristics corresponding to the metal elements.
For example, since alkaline earth elements are used for desulfurization and the like, desulfurization performance can be expected to be provided by supporting alkaline earth elements on woody biomass.
In the case of a metal element having a high ionization tendency, it is considered that high-concentration ionic water can be repeatedly produced by putting a metal carrier in water.
Further, in the case of a metal element that is easily combined with oxygen like titanium, it is considered that it is supported in the form of a metal oxide.

Using the apparatus shown in FIG. 1, a metal support of woody biomass was actually produced.
The plasma reaction tube furnace 5 is made of quartz and has an outer diameter of 300 mm, an inner diameter of 290 mm, and a length of 1000 mm so that the inside can be easily seen from a transparent quartz tube. The electromagnetic induction coil 4 was wound 38 times around a quartz reaction tube furnace 5 using a copper pipe having a diameter of 6 mm.
The high frequency power supply 3 was set to oscillate a high frequency of 360 kHz.

As a first sample, softwood wood chips were prepared and crushed with a pulverizing mixer, and processed into wood flour having a diameter and length of about 0.5 mm to 1 mm.
As a second sample, a commercially available drip-type instant coffee sip was prepared and dried sufficiently.

The first plasma irradiation step was performed as follows.
First, about 5 g of sample wood powder was thinly spread on the quartz flat plate in advance and inserted into the plasma reaction tube furnace 5.
Thereafter, oxygen gas of high purity (G2 class: purity 99.999%) was sent from the oxygen gas cylinder 6 into the plasma reaction tube furnace 5 at a rate of 1 L / min. Further, the pressure in the reaction furnace was maintained at about 5 Torr by the balance between the supply amount of oxygen gas from the oxygen gas cylinder 6 and the exhaust amount of the vacuum pump 10.
Then, a high frequency anode voltage of 3 kV was applied from the high frequency power source 3 to generate a uniform light purple plasma glow discharge in the plasma reaction tube furnace 5.

The second plasma irradiation step was performed as follows.
In the case of supporting silver, silver nitrate powder (a predetermined amount of 3 to 10 g) was spread on an iron plate, and this iron plate was inserted into the plasma reaction tube furnace 5. And the vaporized gas plasma of the silver melted and vaporized was generated through the iron plate heated by the high frequency induction heating.
When sodium is supported, sodium amide powder (a predetermined amount of 3 to 10 g) is spread on an iron plate, and the iron plate is inserted into the plasma reaction tube furnace 5. Then, a vaporized gas plasma of sodium melted and vaporized was generated through an iron plate heated by high frequency induction heating.
In the case of supporting titanium oxide, a titanium tetrachloride liquid (100 mL) is poured into a beaker, and the beaker is inserted into the plasma reaction tube furnace 5 to be vaporized due to the vaporization promoting effect under reduced pressure. A vaporized gas plasma of titanium tetrachloride was generated.
After that, when irradiated with silver nitrate plasma and titanium tetrachloride plasma, washing with distilled water was performed. On the other hand, when sodium amide plasma was irradiated, cleaning was not performed in consideration of the reactivity between sodium and water.

Here, the oxygen plasma irradiation time in the first plasma irradiation step is changed to six stages from 5 minutes to 150 minutes, and multi-measurement by XPS (X-ray photoelectron spectroscopy) is performed on the samples of each irradiation time. Went.
From the measurement results, it was found that the relative content of carbon atoms and oxygen atoms, which are the main components of the wood flour, changes depending on the irradiation time of the oxygen plasma to the wood flour. Specifically, as the irradiation time increases, the relative content of carbon atoms decreases and the relative content of oxygen atoms increases. However, when the irradiation time exceeds 120 minutes, the relative content remains almost constant. I found out that
As for the second plasma irradiation process, the same experiment was conducted with the plasma irradiation time being changed to six stages, and it was found that when the irradiation time was 30 minutes or longer, the metal adsorption amount maintained a constant value. It was.
Based on this result, hereinafter, the irradiation time of oxygen plasma in the first plasma irradiation step was set to 120 minutes, and the irradiation time of the second irradiation step was set to 30 minutes.

Each sample subjected to the plasma irradiation step was washed with distilled water and then subjected to XPS measurement. In the XPS measurement, an Al monochromatic line was used as the excitation X-ray source, the measurement voltage was 15 kV, and the output was 400 W. In addition, the measurement was performed in the original state of the sample without performing the vapor deposition work on the ion gun and the sample surface.
Moreover, XPS measurement was also performed on wood flour of the original sample that was not subjected to the plasma irradiation process.
FIG. 2 shows the XPS measurement results of the wood powder after the titanium tetrachloride plasma irradiation.
The XPS measurement result of the wood flour after sodium amide plasma irradiation is shown in FIG.
FIG. 4 shows the XPS measurement result of the wood powder after the silver nitrate plasma irradiation.

As shown in FIGS. 2 to 4, by irradiating each precursor gas plasma containing titanium, sodium, and silver, spectral peaks of titanium, sodium, and silver newly appeared, respectively.
Further, although not shown, in the case of the original sample not subjected to the plasma irradiation step, naturally, the peaks of titanium oxide, sodium and silver did not appear except for oxygen and carbon.
In FIG. 2, the spectrum peak of chlorine did not appear. This means that chlorine was removed during the water cleaning after the titanium tetrachloride plasma irradiation.
3 and 4, no nitrogen peak was observed.

Samples of non-plasma-irradiated original sample, sample subjected only to the first plasma irradiation step (oxygen plasma irradiation), and three types (titanium, sodium, silver) samples subjected to the second plasma irradiation step Table 1 summarizes the concentrations of oxygen, carbon, titanium, sodium, and silver.
In addition, as a comparative control, the sample was measured when the irradiation with oxygen plasma was omitted and the wood powder was directly irradiated with silver nitrate gas plasma. Each concentration of the sample to be compared is shown in Table 1 as ^* AgNO ₃ .

The metal can be supported on the cellulose surface by covalently bonding the cellulose molecule and the metal. However, the lignin component serves to block the covalent bond between the cellulose molecule and the metal.
Therefore, it is necessary to oxidize and fix lignin by the strong oxidizing power of ozone.
From Table 1, in the case of oxygen plasma irradiation, an increase in oxygen concentration of 36% was confirmed compared to the original. From this, it can be sufficiently estimated that the lignin component in the wood flour was oxidized with ozone. As a result, the target metal could be supported on the wood chip at a ratio of 1% to 4%.
Moreover, the silver content concentration of the sample of ^* AgNO _{3 in} Table 1 was 0.75%, and it was found that if the oxygen plasma irradiation step was omitted, the silver powder was not sufficiently supported on the wood flour.
Therefore, ozone oxidation of lignin is one of the important processes for supporting metal on wood flour.

  The second sample coffee grounds were also tested in the same manner as the first sample wood flour. Table 2 shows the concentrations of oxygen, carbon, titanium, sodium, and silver in each sample of the second sample (coffee grounds).

From Table 2, the metal content of the metal support subjected to the second plasma irradiation step was only 1% or less.
The components of coffee are generally 10% cellulose and 5% lignin, which is 1/5 or less of wood flour. Thus, it is considered that the small proportion of the component that is oxidized by ozone is the cause of the small content of the supported metal. In fact, comparing the original sample with the sample only with oxygen plasma irradiation, the amount of increase in oxygen is considerably smaller than in Table 1, confirming this assumption.

(Hydrophilicity test)
In general, once a sample is exposed to oxygen plasma, the surface of the sample is modified with functional groups rich in hydrophilicity.
Here, the change in hydrophilicity by the plasma irradiation process was examined.
About 2/3 of a 200 mL glass beaker was filled with distilled water, and 3 g of each wood flour sample was gently dropped onto the liquid surface.
And time until 90% of wood flour reached the bottom of the container was measured. About 10% of the wood flour was excluded because it stagnates on the liquid surface due to the adhesion of dust and the overlapping of the powder.
The submerged sedimentation and submergence time of the original sample of non-plasma irradiation, the sample subjected to only oxygen plasma irradiation, and the three types of wood flour samples carrying each metal were measured. The measurement results are shown in FIG.
As shown in FIG. 5, in the case of the original wood flour, it took 352 seconds for the wood flour to reach the bottom of the container. On the other hand, it was found that when this original wood powder was irradiated with oxygen plasma, the hydrophilic performance was drastically improved. In addition, when the metal is supported, the hydrophilicity is lowered, and it can be seen that the metal acts on the hydrophilic functional group.

Next, FT-IR measurement was performed on each sample in order to confirm that the functional group rich in hydrophilicity was surely modified on the sample surface by oxygen plasma irradiation.
First, the measurement result of the original wood flour is shown in FIG. 6A, and the measurement result of the sample subjected to only oxygen plasma irradiation is shown in FIG. 6B.
As shown in FIG. 6A, there is no significant functional group with respect to the original wood flour.
However, as shown in FIG. 6B, in the case of sample subjected to oxygen plasma irradiation, appearing the peak of the C-O bond in the vicinity of wave number 1030 cm ^-1, also the benzene ring in the vicinity of 1500 cm ^-1 it is, 2900 cm ^-1 -COOH (carboxyl group) appeared in the vicinity of-, and -OH (hydroxyl group) appeared in the vicinity of 3300 cm- ¹ .

The reason why such a functional group is modified on the surface of the wood flour by irradiation with oxygen plasma is considered to be due to the following plasma chemical reaction.
When the surface of the wood powder is irradiated with the low temperature plasma, the molecular bonds constituting the wood powder, that is, C—H bonds are cut by the strong electron energy of the plasma, and the hydrogen atoms are light and are immediately extracted. At this time, when oxygen gas is introduced as a plasma precursor, oxygen molecules themselves combine with oxygen atoms to generate ozone. At the same time, the plasma _{reactor, · OH, · H, O} 2 - , etc. active species often are produced of. As a result, these active species react with the wood powder from which hydrogen atoms have been extracted, so that oxygen-rich functional groups such as —CO—, —COOH, and —OH are modified on the surface.

The measurement results of the FT-IR measurement of each sample supporting a metal in the second plasma irradiation step are shown in FIGS. 7C to 7E. FIG. 7C shows the measurement results of the sample irradiated with titanium tetrachloride plasma. FIG. 7D shows the measurement results of the sample irradiated with sodium amide plasma. FIG. 7E shows the measurement results of the sample irradiated with silver nitrate plasma.
As shown in FIGS. 7C to 7E, the functional group that appeared in FIG. 6B does not appear.
This confirms that the metal was substituted and supported at the tip of the modified functional group. For example, one of the bonds of a divalent carbonyl group is substituted with a metal, and the hydrogen atom of a monovalent hydroxyl group or carboxyl group is substituted with a metal.

(Silver ion concentration of silver ion water)
Assuming the case where silver ion water was produced from a silver support of woody biomass, the concentration of silver ions in silver ion water was examined.
Specifically, 3 g of wood powder adsorbed with silver was put into a beaker containing 100 mL of distilled water, and the time change of the silver ion concentration was measured.
When the wood powder sample on which silver was adsorbed was gently scattered on the water surface in the beaker, the sample started to be submerged. When about 90% of the sample was submerged, the measurement of the silver ion concentration was started.
The silver ion concentration was measured by attaching a silver ion composite sensor (measurement range: 0.1 mg / L to 108,000 mg / L, Ag ⁺ ) to a portable ion / PH meter.
The time change of the silver ion concentration obtained by the measurement is shown in FIG.
The first experiment (run1) shown in FIG. 8 is a time change of the silver ion concentration measured in this state. The concentration was about 40 mg / L at the start of measurement, but the concentration decreased with time. The main cause of this decrease is considered to be that with the expression of the hydroxide ion OH ^{− in} water, the silver ion reacts with it to change to silver hydroxide and further to silver oxide. In fact, after 30 hours, adhesion of a brown solid, which seems to be silver oxide, was confirmed on the inner wall of the water container.

As the second experiment, the used sample of the first experiment was dried for 24 hours, and again gently poured into a beaker containing 100 mL of distilled water as in the first experiment. The time change was measured. The measurement result is shown as run2 in FIG.
At the start of the second measurement (run2), the concentration was slightly reduced compared to run1, but after a period of 10 hours, 0.63 mg / L, which was almost the same concentration as run1, was shown.
This means that an active metal species having a highly reusable catalytic function was generated in the wood flour. A report that most fungi are sterilized at a silver ion water concentration of 0.1 mg / L (for example, Kishiji Satoshi, “Current Status and Challenges of Antibacterial Metallic Materials”, Materia, Vol.39, p.146- 150, (2000), and Uchida et al., “Antimicrobial activity of silver ions in a minimum growth inhibitory concentration environment”, Journal of Antifungal Society, Vol.32, p.115-121, (2004)). Judging, it can be said that 0.63 mg / L is a sufficiently high concentration for sterilization.

As a third experiment, a wood powder sample adsorbed with silver obtained in the same manner as the sample used in the first experiment was put into a beaker containing 100 mL of distilled water, and the silver ion concentration was measured. The attenuation characteristics were investigated. However, before the measurement was started, the sample was stirred in water and the beaker containing the sample was shaken at a rate of 100 times per minute for 30 minutes. Then, the sample was removed from the beaker, and the silver ion concentration contained in the water inside the beaker in that state was measured. The measurement result is shown as run 3 in FIG.
In the third experiment (run 3), a high concentration of 139 mg / L of silver ions appeared at the start, and no extreme decrease in concentration was observed over time. The concentration was 117 mg / L after 15 hours and 112 mg / L after 30 hours.
This is presumably because the reaction change to silver oxide in the sample solution reached saturation, so that the silver ion concentration maintains a substantially constant value.

In the second plasma irradiation step, the amount of silver nitrate inserted as a precursor in the furnace was set to 5 g and 10 g, and wood powder samples each adsorbing silver were prepared.
The time change of the silver ion concentration was examined for each prepared sample. The experimental conditions were the same as those in the first experiment (run 1) in FIG.
As a measurement result, the time change of the silver ion water concentration normalized with reference to the concentration at the start of measurement as 100% is shown in FIG.

From FIG. 9, in any sample, the silver ion concentration in the silver ion water decreases with the passage of time.
In addition, when the amount of silver nitrate is increased to 10 g, the decreasing rate of the silver ion concentration is reduced. This is considered to be because when the amount of silver nitrate inserted as a precursor in the plasma reaction tube furnace 5 is increased, the amount of silver evaporation increases, and as a result, the silver ion concentration increases.
In the case of a 10 g sample of silver nitrate, 80% of the initial concentration was maintained even after 2 hours, and 75% was retained even after 24 hours.
However, if the amount of silver nitrate as the precursor is increased, the amount of vaporized material that is exhausted from the plasma reaction tube furnace 5 via the vacuum pump 10 is also increased, which is commensurate with the amount of wood powder sample. There is an appropriate amount of precursor. In other words, it is important that the vaporized substance is effectively adsorbed on the carrier without exhausting the vaporized substance through the vacuum pump.

(Verification of bactericidal effect)
Silver ions themselves are harmless to the human body and have strong bactericidal power against most bacteria (Legionella, Salmonella, Staphylococcus aureus, Pseudomonas aeruginosa, Escherichia coli O-157H7, Helicobacter pylori), etc. The point is drawing attention.
Therefore, a demonstration experiment of the bactericidal effect of the silver support of woody biomass was performed as follows.

Bactericidal effects were confirmed by colony inspection using the following Petri film using general live bacteria attached to the surface of Myanmar black sesame seeds.
First, after putting black sesame into distilled water, it is thoroughly stirred with a stir bar. Thereby, all the adherent bacteria are released into water.
Next, 1 mL of the distilled water was inoculated on the Petri film medium, and cultured in an incubator for 48 hours under conditions of a culture temperature of 35 ° C. and a carbon dioxide gas concentration of 5%.
After 48 hours, the bactericidal effect was evaluated by counting the colonies of bacteria forming red spots.

The result of culturing general viable bacteria collected from black sesame is shown in the photograph of FIG. 10A. In this case, 157 colonies were confirmed.
On the other hand, the result in the case of culturing after pouring general viable bacteria into silver ion water having a silver ion concentration of 100 ppm for 5 minutes is shown in the photograph of FIG. 10B. In this case, no colonies were confirmed, demonstrating that the bacteria were killed immediately.
Moreover, the result at the time of culture | cultivating after throwing a general living microbe into the acidic water adjusted to pH = 3.46 for 5 minutes is shown in the photograph of FIG. 10C. This is a study of the influence of acidity on sterilization because the silver ion water used was pH = 3.46. In this case, 111 colonies were detected. From this, it was confirmed that the killing of the bacteria was not due to the influence of acidity but due to silver ions.

(Characteristic evaluation of sodium carrier)
Similar to the silver carrier sample, a sodium-loaded sample was put into water and the concentration of expressed sodium ions was examined.
The powder in which sodium was adsorbed was gently put into 100 mL of distilled water by 0.1 g, and the sodium ion concentration in the water was read with a sodium ion electrode that was always inserted in the water each time the powder was added. The total amount of 2.0 g was charged and the charging was finished.
As a measurement result, the relationship between the amount of the input sample and the concentration of sodium ions is shown in FIG.

FIG. 11 shows that the concentration of sodium ions increases as the amount of sample put into water increases.
When a total amount of 2.0 g of sodium carrier was added, the concentration of sodium ions was about 20 mg / L.

Then, the adsorption | suction effect of chlorine was investigated about the sodium support | carrier of woody biomass.
Using a 37% strength aqueous hydrogen chloride solution (hydrochloric acid), the state of chlorine bonding to the sodium carrier under reduced pressure and plasma irradiation was examined.
A beaker containing 10 mL of hydrochloric acid and a 2.5 g sample of sodium support were loaded into a quartz reaction tube furnace and left under reduced pressure (the furnace was maintained at 5 Torr) for 30 minutes, and a high frequency power supply anode voltage of 3 kV was applied. Two types of experiments were conducted, in which hydrogen chloride gas plasma was generated and exposed to the hydrogen chloride gas plasma for 30 minutes.
For each sample after the experiment, multi-measurement by XPS was performed to measure the ratio of chlorine contained in the sodium carrier.
The measurement results are shown in Table 3.

From Table 3, it was found that even under a reduced pressure state where no plasma is generated, the wood powder carrying sodium deprives chlorine from hydrogen chloride and adsorbs chlorine to the wood powder.
When the plasma is irradiated, the hydrogen chloride gas itself is ionized into hydrogen ions and chlorine ions by the plasma, so that the adsorption ratio to the wood powder becomes larger than that under the reduced pressure condition.

Here, when the binding energy value of the Na band was examined by XPS measurement, a peak was recognized in the vicinity of 1072.5 eV. Since this peak position corresponds to NaCl which is a Na compound, it was confirmed that the adsorption of chlorine was achieved by the production of a compound containing NaCl.
The binding energy value of the Na band was the same in both the decompression condition and the plasma condition.

The lignin component of the metal carrier of woody biomass according to the present invention is similar in molecular structure to dioxins that cause soil contamination. In addition, when wood decays, the presence of white-rot fungi (a type of mushroom) that has enzymes that decompose lignin, a component of the wood, has now been revealed.
Therefore, bioremediation technology that collects this bacterium and purifies soil contaminated with dioxins and decomposes various persistent compounds such as dioxins has been studied.
In addition, when it becomes sodium ion water and soaks in contaminated soil, the ion water promotes dechlorination by its strong adsorption function and adsorbs it, not only chlorine but also various metals and ions. It becomes a contained solution and penetrates deep underground. The solution is thicker than the concentration in the equilibrium state, and a solute containing many molecules and ions is mixed there. Further, the supersaturated state is once achieved by the underground pressure. Next, in this state, a solid crystal is instantaneously generated by some trigger (for example, ground vibration). In this way, heavy metals can be expected to become components in the crystal and be fixed underground.

(Measurement of photocatalytic function)
In order to investigate the photocatalytic function of the titanium dioxide support of woody biomass, the degree of odor adsorption was measured using an odor monitor (OMX-SR).
Each sample of the original wood flour and titanium dioxide carrier was prepared.
First, 3 g of each sample was inserted into a sealed container filled with incense smoke, and the odor was adsorbed to the wood flour for 60 minutes.
Next, after taking the wood flour sample from the sealed container, the sampling port of the odor monitor was inserted into each wood flour, and the odor intensity was measured. In this odor monitor, the odor intensity is indicated by a dimensionless number. If the odor intensity is small, the odor is weak, and if the odor intensity is large, the odor remains and indicates that it is strong.
Furthermore, the wood flour sample taken out from the sealed container was exposed to ultraviolet rays having a wavelength of 253.7 nm for 3 hours. Here, the output of ultraviolet rays was 4.9 W, and the radiation intensity of ultraviolet rays was 51 μW / cm ² .
The odor intensity was measured again for each sample exposed to ultraviolet light.
Table 4 shows the measurement results of odor intensity. In Table 4, “Before” indicates the odor intensity before exposure to ultraviolet rays, and “After” indicates the odor intensity after exposure.

The original wood flour sample did not show photocatalytic properties, and the odor did not change even when irradiated with ultraviolet rays.
On the other hand, the odor intensity of the titanium dioxide carrier sample after UV irradiation decreased to 1/3 before irradiation. From this, it has been found that most of the odor is not physically adsorbed but chemically bonded and decomposed by the photocatalyst.

Wood powder carrying titanium oxide has not only a deodorizing function but also an antibacterial function.
Therefore, the titanium oxide carrier can be expected to be applied not only as a deodorizing material such as a filter material for decomposing tobacco smoke, but also as an air cleaning / antibacterial material in hospitals, for example.

  Subsequently, each sample surface was observed with an SEM (scanning electron microscope). The observation results are shown in the photographs of FIGS. 12A to 12E. FIG. 12A shows an original wood flour sample (1000 × magnification). FIG. 12B shows a sample irradiated with oxygen plasma alone (magnification 1000 times). FIG. 12C shows a sample of titanium oxide support (magnification 1000 times). FIG. 12D shows a sample of sodium carrier (1000 × magnification). FIG. 12E shows a sample of the titanium oxide carrier (5000 × magnification).

As can be seen by comparing FIG. 12A with other photos, the surface exposed to the plasma is less smooth than the surface of the unirradiated original wood flour.
As shown in FIG. 12B, a uniform long stripe pattern appears in the sample irradiated with only oxygen plasma.
As shown in FIGS. 12C and 12D, the entire surface of the metal carrier is porous. This is evident in the case of sodium carriers. Then, as shown in FIG. 12E, when enlarged and observed, it is found that the titanium oxide support is quite rich in porosity.

From the observation result by SEM, quantitative characteristics such as the specific surface area of the porous surface and the average pore diameter are unknown.
However, it was confirmed that it is important that the metal support of the woody biomass is rich in porosity in order to develop metal ions and photocatalytic properties.

  The present invention is not limited to the above-described embodiments and examples, and various other configurations can be taken without departing from the gist of the present invention.

It is a schematic block diagram of one form of the manufacturing apparatus of the metal carrier of woody biomass. It is a XPS measurement result of the wood powder after titanium tetrachloride plasma irradiation. It is a XPS measurement result of the wood flour after sodium amide plasma irradiation. It is a XPS measurement result of the wood flour after silver nitrate plasma irradiation. It is a figure which compares and shows in-water sedimentation and submergence time of each sample. It is a figure which shows the FT-IR measurement result of each sample of A and B. It is a figure which shows the FT-IR measurement result of C-E each sample. It is a figure which shows the time change of silver ion concentration. It is a figure which shows the time change of the normalized silver ion water density | concentration. It is a photograph which shows the result of the culture test of AC general live microbe. It is a figure which shows a sodium ion concentration when a sodium carrying powder sample is thrown into water. It is a photograph which shows the observation result by SEM of each sample surface.

Explanation of symbols

1 water tank, 2 pumping pump, 4 copper pipe, 5 plasma reaction tube furnace, 6 O ₂ gas, 10 vacuum pump

Claims (8)

For woody biomass
A first plasma irradiation step of irradiating oxygen plasma;
Performing a second plasma irradiation step of irradiating a plasma containing a metal element,
A metal supporting method for wood biomass, characterized in that the metal element of the plasma irradiated in the second plasma irradiation step is supported on the wood biomass.   The method for supporting metal on woody biomass according to claim 1, wherein in the second plasma irradiation step, silver nitrate is used to generate plasma containing silver.   The method for supporting metal on woody biomass according to claim 1, wherein in the second plasma irradiation step, sodium amide is used to generate a plasma containing sodium.   The method for supporting metal on woody biomass according to claim 1, wherein in the second plasma irradiation step, plasma containing titanium is generated using titanium tetrachloride.   A metal carrier for woody biomass, wherein a substance containing a metal element is supported on the woody biomass.   6. The woody biomass metal carrier according to claim 5, wherein any one of silver, sodium, and titanium oxide is supported as the substance containing the metal element.   A method for producing silver ion water, comprising: putting the silver support of the woody biomass produced by the metal loading method on the woody biomass according to claim 2 into water and eluting silver ions into the water. A method for producing sodium ion water, wherein the sodium support of the woody biomass produced by the method for supporting metal on a woody biomass according to claim 3 is put into water and sodium ions are eluted into the water.