Patent Application
20200095130
The present invention relates to a producing device for efficiently extracting amorphous silica from a vegetable material, a method for producing the amorphous silica, silicon produced from the amorphous silica, and a method for producing the silicon.
Conventionally, silica which is fine silicon dioxide has a lower water absorption property than general powder has. Due to this property, silica is used for preventing solidification caused by moisture in cosmetics such as eye shadow and foundation, and is used in cream and milky lotion for stabilization, or the like. In addition, silicon dioxide is also used as negative electrode material for battery material using highly pure silicon.
Among these kinds of silica, crystalline silica is known to be a hazardous substance. However, amorphous silica is not designated as a hazardous substance and can be used for cosmetics, foods (including supplements), agricultural fertilizers, and feeds (for livestock and for pet animals).
For example, JP 2014-181144 A discloses chaff charcoal or rice straw charcoal rich in amorphous silica, obtained by using a carbonizing device to carbonize chaff or rice straw in an oxygen-free atmosphere while stirring the chaff or the rice straw. The temperature range for carbonizing the chaff or the rice straw in the carbonizing device is 500° C. to 700° C. Further, JP 2014-181144 A discloses an invention of a method of producing amorphous silica in which the chaff charcoal or the rice straw charcoal is stirred with ion-exchange water in the range of 30 to 100° C., and amorphous silica contained in the chaff charcoal or the rice straw coal is dissolved in the ion-exchange water to be extracted.
Patent document 1: JP2014-181144 A
However, in the conventional producing method, since organic matter such as cellulose is burned to extract amorphous silica, if the temperature is too low, a firing process takes time and may take about 3 hours or longer. Therefore, the conventional method is not suitable for mass production and the extraction amount per hour is not much. Further improvement is required for mass production.
The present invention has been made to solve the above problems, and an object of the present invention to provide amorphous silica capable of extracting as much amorphous silica as possible and capable of increasing the extraction amount per hour, a device for producing the amorphous silica, a method for producing the amorphous silica, silicon produced from the amorphous silica, and a method for producing the silicon.
A method for producing amorphous silica includes:
a pretreatment process of pulverizing vegetable material to obtain a silica source;
a burning process of burning the silica source and extracting silica; and
a purification process of removing carbon from burning material obtained in the burning process,
the burning process including a heating process of supplying an inert gas into a chamber and heating the silica source in the chamber in a plasma atmosphere.
According to the above characteristics, the present invention is capable of producing amorphous silica inexpensively and efficiently in a short time, and enables production of highly pure amorphous silica and production of highly pure silicon by using the highly pure silica.
Amorphous silica, a device for producing the amorphous silica, a method for producing the amorphous silica, silicon produced from amorphous silica, and a method for producing the silicon according to the present invention will be described in detailed with reference to the drawings. Note that embodiments and drawings to be described below are examples of part of the embodiments of the present invention, are not intended to limit the present invention to these configurations, and can be appropriately modified within a range not deviating from the gist of the present invention.
A vegetable material 9 which is a biomass material for producing amorphous silica of a first embodiment or a second embodiment will be described. In the present invention, amorphous silica and silicon which are final products are produced by using the vegetable material 9 which is food residue or material to be discarded. Plants, lumber, or the like is used as the vegetable material 9. However, if a vegetable material 9 to be discarded such as residues generated when plants are harvested is used as raw material, it is possible to obtain raw material at low cost.
Table 1 is a composition table of the vegetable materials 9. In Table 1, ratios of the components constituting the raw material indicated in the leftmost column are indicated in percentage in the subsequent right columns. For example, rice straw contains 37.4% carbon (C), 0.53% nitrogen (N), 0.06% phosphorus (P), 0.14% phosphoric acid (P2O5), 1.75% potassium, 2.11% potassium oxide (K2O), 0.05% calcium (Ca), 0.19% magnesium (Mg), and 0.11% sodium (Na).
Here, as illustrated in
There is a compressed narrow cell line between silicided cell lines and it is possible to obtain amorphous silica having a great specific surface area by removing a carbide after carbonization. As described above, the vegetable material 9 containing a large amount of, that is, 13% or more and 35% or less of silicic acid is suitable.
Table 1 illustrates examples of the vegetable material 9 which contains a relatively large amount of silicon. The examples include, in addition to rice straw, wheat straw, barley straw, rice bran,chaff, buckwheat straw, soybean straw, sweet potato vine, a turnip leaf, a carrot leaf, a corn calm, a sugar cane crown, a palm cake, a peanut shell, mandarin orange peel, red cedar sawdust, bark of larch, and a fallen leaf of ginkgo. In addition, a plant itself rather than the residue thereof may be used.
For example, bamboo contains fiber material made of cellulose, hemicellulose, lignin, and minerals such as iron, magnesium, calcium, manganese, copper, and nickel. In addition, when bamboo or a bamboo leaf is fired, a silanol group (Si—OH) is extracted and is converted into SiO4, and SiO4 is extracted in the process of firing.
Tables 2 and 3are composition tables of the vegetable material most suitable for the method of producing amorphous silica, or silicon, from among the vegetable materials 9 in Table 1 described above in the present invention. Table 2 illustrates ratios of the components constituting the raw material indicated in percentage. For example, water content is 8% to 10%, ash content is 15% to 18%, lipid is 0.1% to 0.5%, lignin is 18% to 25%, hemicellulose is 16% to 20%, cellulose is 30% to 35%, and others are 5% to 10%. As described above, main components of the organic matter which becomes a carbide are lignin, hemicellulose, and cellulose.
Table 3illustrates chemical composition of the inorganic matter of the vegetable material 9 illustrated in Table 2. In the vegetable material 9 illustrated in Table 2, the organic matter such as cellulose is 80 wt %, and the inorganic matter is 20 wt %. The chemical composition of the inorganic matter of Table 3 is as follows: SiO2 is 92.14 wt % , Al2O3 is 0.04 wt % CaO is 0.48 wt %, Fe2O3 is 0.03 wt %, K2O is 3.2 wt %, MgO is 0.16 wt %, MnO is 0.18 wt %, and Na2O is 0.09 wt %. The vegetable material 9 illustrated in Table 2 contains a large amount of silicon oxide (SiO2) as inorganic matter.
A plasma device 10 according to the first embodiment will be described with reference to
Argon was mainly used as the inert gas 6 contained in a gas cylinder; however, examples of the inert gas 6 include helium, neon, and nitrogen. The inert gas 6 can be filled into the chamber 1 from an introduction pipe 7 via a gas amount control device 21. The gas amount control device 21 is capable of adjusting the flow rate of the inert gas 6.
The chamber 1 is connected to a control valve 22, and the inside of the chamber 1 can be depressurized to a vacuum state by the vacuum pump 30. The control valve 22 is connected to the chamber 1 to introduce the inert gas 6 into the chamber 1. A leak valve 23 for releasing the vacuum state in the chamber 1 to atmospheric pressure is provided between the control valve 22 and the chamber 1. A control valve 14 and a leak valve 15 for releasing the vacuum state in the chamber 1 to the atmospheric pressure are also provided between a lead-out pipe 8 for introducing the air in the chamber 1 and the vacuum pump 30.
In addition, a temperature control device 24 controls a high-frequency power supply 4 so as to manage temperature retention and temperature retention time, and the like inside the chamber 1. The plasma device 10 of the present first embodiment adopts a method of filling, as a working gas, argon gas which is the inert gas 6 described above under low pressure close to the vacuum state, and making a high current flow between a cathode 2 and an anode 3 which are electrodes, and obtaining thermal plasma produced by arc discharge. A crucible 5 made of carbon is disposed between the cathode 2 and the anode 3, and the above-described vegetable material 9 is put in the crucible 5. Silica ash 19 is extracted by heating the vegetable material 9 for about 10 to 30 minutes in the temperature range from 800° C. to 1150° C. by thermal plasma produced by arc discharge.
A plasma device 100 according to another modification of the first embodiment will be described with reference to
By using the plasma device 10, 100 as described above, even lignin which is difficult to be thermally decomposed can be decomposed.
Note that besides the plasma devices described above, there is a method of producing thermal plasma by a plasma device using barrier discharge, corona discharge, pulse discharge, and DC discharge.
It is possible to heat a heating furnace 42 to a high temperature close to 2000° C. The silica ash 19 is put in the large crucible 50, the air is made to flow through the large crucible 50, and heating treatment is performed at a temperature of 600° C. or higher and 1000° C. or lower.
The same reference numerals are given to configurations the same to as those in the first embodiment and a description thereof will be omitted. The present embodiment represents the burning process S2 of the production processes to be described later. In
Here, oxidation inhibiting substance 70 may be any substance as long as the substance enables burning while suppressing oxygen concentration in order to prevent oxidation at the time of burning, and a gas or a liquid of a halide (carbon dioxide, nitrogen, Halon 2402, Halon 1121, Halon 1301) may be mixed and burned.
Thereafter, the atmosphere in a furnace 81 of a combustion furnace 80 is set to 800° C. or higher, and the vegetable material 9 is burned for 3 to 5 hours under the conditions of 20 atm and 400° C. or higher and 900° C. or lower.
With reference to
The silica ash producing device 200 is provided with a plurality of storage containers 205 for containing the vegetable material 9 inside a see-through quartz tube 203 in order to mainly enable mass production.
First, with reference to
Note that the quartz tube 203 may be detached and fixed from both sides of the left and right flanges 231, 232 so as to be sandwiched by the left and right flanges 231, 232.
As illustrated in
In addition, the control valve 224 allows one of the inert gas 217 and the combustion gas 218 to flow into the quartz tube 203 in a switchable manner according to the temperature condition and the burning time depending on the process.
A control device 210 performs control such that the internal pressure of the quartz tube 203 can be set to a vacuum pressure, an atmospheric pressure, or 20 atm or higher by using a dry pump 223 connected to the pressure control valve 222 and the control valve 224.
As illustrated in
The high-frequency coil 240 is formed so as to surround the periphery of the quartz tube 203, and a coil support tool 242 for supporting a coil 243 is fixed to a driving device 1 (214). The driving device 1 (214) moves along rails 236 in the X, -X directions. A motor is used as the driving device 1 (214). Note that linear driving or the like may be used in lieu of the motor.
Although the principle and production processes of the silica ash producing device 200 are the same as those of the plasma device 100 of the second embodiment described above, the silica ash producing device 200 differs from the plasma device 100 in that the high-frequency coil 240 is movable in the X and -X directions. Once the high-frequency coil 240 is installed, it is possible to sequentially carbonize the plurality of storage containers 205 storing the vegetable materials 9. Therefore, it is possible to carbonize a large amount of the vegetable materials 9 at a time. Mainly, in the production processes, the high-frequency coil 240 can be utilized in a carbonization process in S2 in
In addition, the high-frequency coil 240 is provided with a shielding plate 241 in the vicinity of the coil 243 to reduce the influence of electromagnetic waves emitted from the coil 243.
The silica ash producing device 200 makes inert gas 217 flow and applies a high-frequency magnetic field of 4 MHz from a high-frequency power supply 212 to the high-frequency coil 240. Therefore, as illustrated in
By using the high-frequency coil 240 and the inert gas 217 as described above, even lignin which is difficult to be thermally decomposed can be decomposed. In addition, it is optimal for mass production since no toxic substances and the like are generated in the production processes.
Note that besides the plasma device described above, there is a method of producing thermal plasma by a plasma device using barrier discharge, corona discharge, pulse discharge, and DC discharge.
The high-frequency power supply 212 is provided with a water-cooling type cooling device 213 for cooling the coil 243 and the power supply. A filter 221 formed of a nonwoven fabric, cotton, paper, or the like is provided in order to prevent a tar component or the like generated during burning in the quartz tube 203 from affecting the dry pump 223.
In addition, in a temperature control device 211 illustrated in
The electric furnace 250 is formed so as to surround the periphery of the quartz tube 203, and is fixed to a driving device 2 (216). The driving device 2 (216) moves along the rails 236 in the X, -X directions. A motor is used as the driving device 2 (216). Note that linear driving or the like may be used in lieu of the motor.
The electric furnace 250 can raise the temperature up to about 2000° C., and can burn the inside of the quartz tube 203 when refining the vegetable material 9 and the silica ash 19 while supplying the combustion gas 218. In addition, the combustion gas 218 is used for assisting burning, and oxygen or the like is considered as the combustion gas 218. The combustion gas 218 is mainly used in a process in the purification process S3 illustrated in
Next, referring to
As illustrated in
The storage container 205 is fixed to a mounting table 206 including a plurality of upper end piece portions 208 which are rod-shaped projecting pieces and provided at four corners on a front surface of the mounting table 206, and a plurality of lower end piece portions 207 which has a piece shape and projects upward at both ends on the back surface of the mounting table 206. A hole into which the piece of the upper end piece portion 208 can be inserted is formed in the storage container 205, the hole being positioned at the location identical to the position of the upper end piece portion 208 located below. The upper end piece portion 208 is fitted in the hole, and the storage container 205 is fixed to the mounting table 206.
The mounting table 206 to which the storage container 205 is fixed is mounted on a base 202 such that the lower end piece portions 207 are fitted into base grooves 204 which are groove provided in the base 202. A plurality of the base grooves 204 is provided such that the base grooves 204 are shifted from each other by Y1 in the width direction such that the storage containers 205 can be disposed so as to be shifted from each other. In addition, the storage containers 205 are separated not only in the width direction but also in the X direction by a predetermined distance X1 as illustrated in
By separating the storage containers 205 in the Y1 direction or the X direction, it is attempted to prevent the storage container 205 other than the target of carbonization from being affected as much as possible during carbonization caused by plasma heat. In addition, in order to enable temperature control, in the base 202, a thermocouple storage space 209 which is a space in which the thermocouple can be fixed is secured in the vicinity of the base groove 204.
As illustrated in
Though the silica ash producing device 200 is configured to obtain silica, it is also possible to extract carbon (graphene) from biomass material depending on temperature conditions. In addition, the electric furnace 250 enables not only the burning process S2 described above but also the purification process S3. Therefore, it is possible to perform various processes while controlling the temperature with identical device.
In the above silica ash producing device 200, since the high-frequency coil 240 or the electric furnace 250, which is a portion applying heat, moves and heats the vegetable material 9 contained in the storage container 205, it is easier to create a space in which pressure can he controlled than in the case of a conveyor type device in which raw material moves. In addition, in the conveyor type device, there is a concern over chemical reaction with oil required for a conveyor or the like, which may cause mixture of impurities. In addition, compared to the conveyor type device, in the silica ash producing device 200, there is no risk of an increase in cost due to complication of the device caused by mixture of inert gas or the like. Since the silica ash producing device 200 is provided outside the quartz tube 203, inspection and maintenance work from the outside is also easy.
In addition, it is also possible to use one device in the processes in the burning process S2 or the purification process S3 to be described later. Further, the silica ash producing device 200 can also produce graphene by changing the temperature conditions. As described above, since the silica ash producing device 200 is a multifunctional device, the device is not only excellent in production efficiency but can be applied to various purposes.
Process Flow of Silica Ash Production
With reference to
First, in the pretreatment process S1, after the vegetable material 9 is dried as described above, the vegetable material 9 is pulverized, and the pulverized vegetable material 9 and a granulating agent are mixed in the ratio of 10 to 1 with water, the mixture is divided into an appropriate size and is kneaded and heated to about 100° C. on a drying device such as a hot plate to evaporate water content and to produce the vegetable material 9.
Here, examples of the pulverizing method include a mill, a blender, a grinder, and the like. In addition, the granulating agent may not be used as long as a net or the like prevents particles from flying in the chamber 1 of the first and second embodiments or the quartz tube 203 of the third embodiment.
Alternatively, the vegetable material 9 may be immersed in a solution obtained by diluting hydrogen chloride (HCL) in the pretreatment process and may be dried, and then the process may proceed to the burning process S2. Part of cellulose is eluted into the diluted hydrogen chloride solution, and the purity after the burning process S2 can be increased.
Next, the burning process S2 in the case of using the plasma device 10, 100 illustrated in
Similarly, the burning process S2 in the case of using the silica ash producing device 200 illustrated in
As illustrated in
In this measurement, rice straw, rice bran, coconut shell, chaff, and peanut shell, and the like were used, and similar results were obtained.
Next, the purification process S3 in the first embodiment will be described. First, the heating furnace 42 of the impurity removing device 40 illustrated in
Similarly, the purification process S3 in the third embodiment will be described. First, the electric furnace 250 of the silica ash producing device 200 illustrated in
With reference to
Silica ash (Si)+3HCl→SiHCl3+H2 Chemical formula 1
In the reaction formula of Chemical formula 1, silicon (Si) of the extracted silica ash is reacted with a HCl gas. Reaction temperature is from 300° C. to 350° C. The product obtained after the reaction is a mixture of trichlorosilane gas (SiHCl3), SiCl4, and chloride. As described above, trichlorosilane gas (SiHCl3) is generated in the metal gas treatment process S4.
SiHCl3+H2→polycrystalline Si+3HCl Chemical formula 2
4SiHCl3→Si+3SiCl4+2H2 Chemical formula 3
This highly pure SiHCl3 and H2 are reacted in a vacuum state and heated to 1500° C. Then, silicon (Si) and 3SiCl4 are produced by reduction reaction of SiHCl3 with H2 as seen in the reaction formula of Chemical formula 2 and thermal decomposition as seen in the reaction formula of Chemical formula 3, and about ⅓ of SiHCl2 forms polycrystalline silicon.
In this manner, highly pure polycrystalline silicon (Si) is produced in the silicon production process S5. This silicon is used as a material of a solar cell, a negative electrode material for a fuel cell, and a material of an electronic circuit such as an LSI device or a VLSI device.
Note that a highly pure polycrystalline silicon can be produced by hydrogen reduction and thermal decomposition of halogenated Si such as silicon tetrachloride (SiCl4), silicon tetrabromide (SiBr4), and silicon tetraiodide (SiI4) in addition o trichlorosilane gas (SiHCl3).
| Number | Date | Country | Kind |
|---|---|---|---|
| 2018-176672 | Sep 2018 | JP | national |
