JP4059395B2 - Biodegradable plastic processing method and system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method and system for treating biodegradable plastics, and more particularly to a system for treating biodegradable plastics with garbage-like organics. The present invention can be effectively applied to the treatment of garbage-like waste mixed with biodegradable plastics.
[0002]
[Prior art]
Conventionally, general-purpose plastics such as polyvinyl chloride and polyethylene that can be melt-formed into a desired shape have been widely used for industrial and household purposes. However, conventional general-purpose plastics hardly decompose in a normal natural environment and there is a risk of dioxin generation at the time of incineration. As one solution to this problem, a plastic having the same basic properties (melt-moldable properties, etc.) as conventional plastics and capable of being decomposed by microorganisms (hereinafter referred to as biodegradable plastics). Is attracting attention and is becoming popular. Biodegradable plastics are produced by natural microorganisms such as carbon dioxide (CO₂) And water, the impact on the environment is small, and it can be expected to contribute to global warming countermeasures compared to conventional plastics derived from fossil fuels.
[0003]
Biodegradable plastics can be classified into microbial production systems, chemical synthesis systems, natural polymer systems, and composite systems based on their production methods. The microbial production system is a plastic using biopolyester or the like that is obtained by cultivating and synthesizing microorganisms with nutrients. The chemical synthesis system is a plastic obtained by chemically processing a polymer (such as polylactic acid) having an ester bond or the like that is easily decomposed by microorganisms from a natural product as a raw material. Natural polymers are plastics that utilize the basic composition of animals and plants such as corn-derived starch and crab shell-derived chitosan (see Non-Patent Document 1).
[0004]
Biodegradable plastics can be expected to be used in various fields. For example, materials for agriculture, forestry and fisheries (multi-films, fish nets, etc.) used in the natural environment, civil engineering and construction materials (insulating materials, difficult to recover civil engineering work) If formwork, sandbags, etc.), outdoor leisure products, etc. are made of biodegradable plastic, natural decomposition can be expected even if left in the ground or in the sea after use. In addition, food packaging supplies made of biodegradable plastic (fresh food trays, instant food containers, lunch boxes, etc.), hygiene articles (paper diapers, etc.), office supplies, daily necessities, miscellaneous goods (cups, garbage bags, toothbrushes, spoons, etc.) Although it is difficult to recycle, it can be collected and composted with garbage, etc., and it can be expected to contribute to a recycling-oriented society by reusing compost as an agricultural material.
[0005]
However, the degradation rate of biodegradable plastics in the natural environment is extremely slow, and it takes a long time for the biodegradable plastics to be completely decomposed by the method of leaving them in the ground or in the sea. On the other hand, Patent Documents 1 to 6 disclose an efficient decomposition method for biodegradable plastics. Patent Document 1 proposes a method of pulverizing biodegradable plastic in a frozen state and disposing it as a powdered resin in a waste disposal site as a method for improving the degradation rate in a natural environment. In addition, although the method of composting with the above-mentioned garbage etc. can be expected to decompose the biodegradable plastic in a relatively short time, the biodegradable plastic is harder to decompose than the garbage, so composting only the garbage Compared with the treatment, the treatment period becomes longer, and the compost quality deterioration becomes a problem as compared with the case of only garbage. In order to improve the efficiency and quality of the composting process, Patent Document 2 performs the composting process, mainly a process of fermenting and decomposing organic waste such as garbage, and mainly a biodegradable plastic product. A method to divide into processes is proposed. In Patent Document 3, garbage collected in a biodegradable plastic bag is separated into a garbage and a biodegradable plastic bag by a selective crushing and sorting device, and the garbage and the biodegradable plastic bag are separately fermented. Proposed method to do.
[0006]
[Patent Document 1]
JP 2002-355819 A
[Patent Document 2]
JP 2001-269652 A
[Patent Document 3]
JP 2001-205233 A
[Patent Document 4]
JP 9-1111036 A
[Patent Document 5]
JP-A-8-038587
[Patent Document 6]
JP 2000-103843 A
[Patent Document 7]
Japanese Patent No. 3064272
[Patent Document 8]
JP 2002-177888 A
[Non-Patent Document 1]
Study Group on Development and Dissemination of Bio-biodegradable Materials “Policy Recommendations for Dissemination of Bio-biodegradable Materials” Mitsubishi Research Institute, Ltd., July 2002
[0007]
[Problems to be solved by the invention]
However, even when crushed as in Patent Document 1, it takes time to disassemble the biodegradable plastics in the natural environment. Therefore, a large disposal space is required to process a large amount of biodegradable plastics in the natural environment. There is a problem that requires. If a large amount of waste is generated with the spread of biodegradable plastics, there is a risk that the treatment plant may become tight. In order to put the biodegradable plastic into practical use, a technique that can decompose the biodegradable plastic in a short time without requiring a large space is useful.
[0008]
On the other hand, Patent Documents 2 and 3 described above can be said to be techniques for composting biodegradable plastics in a short time. However, since the composting process is an aerobic process and it is necessary to supply a large amount of air using a blower or the like at the time of the process, the methods of Patent Documents 2 and 3 have the problem of increasing energy consumption. is there. In order to utilize the characteristics of biodegradable plastics that have a low environmental impact, it is desirable to efficiently decompose the biodegradable plastics with as little energy as possible. In addition, the biodegradable plastic may contain additives and the like for adjusting and improving the quality and strength depending on the application, but in the methods of Patent Documents 2 and 3, the additive in the biodegradable plastic, etc. May be concentrated in compost and may cause safety problems. There is also a need to prevent the additives and the like from being concentrated when biodegradable plastics are decomposed.
[0009]
Therefore, an object of the present invention is to provide a processing method and system capable of efficiently decomposing biodegradable plastic with less energy consumption.
[0010]
[Means for Solving the Problems]
The inventor of the present invention has focused on fermenting and treating biodegradable plastics with anaerobic microorganisms. Conventionally, food waste from households, hotels, restaurants, etc., food manufacturing residue from food factories, etc., agricultural / forestry / livestock / fishery production facilities, processing / dismantling facilities, paper / pulp factories, etc. As for organic waste derived from organisms such as animal and plant residues (hereinafter referred to as “garbage-like organic matter”), a technology has been developed for treating in a relatively short time with anaerobic microorganisms mainly composed of methane fermentation microorganisms. Yes. For example, according to the garbage energy recovery system of Patent Document 7 developed by the present inventors, the garbage-like organic matter finely pulverized into a slurry is obtained by a bioreactor of a high-temperature methane-producing bacterium (hereinafter referred to as a high-temperature bacterium). It decomposes about 90% in 7 to 10 days, and can recover biogas containing methane with high efficiency. Since the system of Patent Document 7 does not require aeration energy, it not only consumes a small amount of energy, but also can recover energy from biogas using a fuel cell or a gas engine. Therefore, if the biodegradable plastic can be subjected to anaerobic fermentation, an extremely energy-saving system can be constructed.
[0011]
However, biodegradable plastics are mainly composed of carbon, hydrogen, and oxygen, and the nitrogen component is insufficient to be decomposed by the system of Patent Document 7. In the fermentation treatment with methane-fermenting microorganisms, if the nitrogen content is reduced, the reaction in the bioreactor does not proceed appropriately, and the amount of methane gas generated may be reduced. The fermentation process also requires trace elements such as metals (Na, K, Mg, Fe, Zn, Ni, Co, etc.). The inventor of the present invention has focused on anaerobic fermentation after mixing biodegradable plastics with garbage-like organic substances, not alone. Garbage-like organic substances contain many proteins with high nitrogen content, for example. If biodegradable plastics and garbage-like organic substances are mixed in an appropriate composition and anaerobically fermented, biodegradable plastics The problem caused by the shortage of nitrogen component can be avoided.
[0012]
However, since the biodegradable plastic is a polymer, the anaerobic fermentation treatment of the biodegradable plastic requires a longer time than the garbage-like organic matter. According to the experiment of the present inventors, when a biodegradable plastic pellet having a diameter of about 3 mm is decomposed by high-temperature methane fermentation, it takes about 90 days to decompose 50%. For this reason, when anaerobic fermentation is performed in a state where garbage-like organic substances are mixed with biodegradable plastics, efficient fermentation treatment becomes difficult in a short time, and problems such as requiring a very large bioreactor arise. As a result of the development and research of the technology that simultaneously fermented garbage-like organic matter and biodegradable plastic, the present inventor has pulverized the biodegradable plastic and mixed it properly with the slurry of garbage-like organic matter. It was found that the slurry can be efficiently decomposed into biogas in the same time as the conventional garbage-like organic matter. The present invention has been completed based on this finding.
[0013]
  Referring to the embodiment of FIG. 1, the biodegradable plastic processing method according to the present invention comprises biodegradable plastic B.Wet pulverizer with liquid injection 16 Circulating channel containing 17 (See Fig. 2)Finely pulverized, mixed plastic slurry D with slurry S of garbage-like organic matter C and brought into contact with methane fermentation microorganisms, and plastic B is treated with methane fermentation in the presence of garbage-like organic matter C It is.
[0014]
  Preferably, the circulation channel 17 including the wet pulverizer 16Circulate toThus, the biodegradable plastic B is pulverized into plastic particles D having an average particle size of about 1 mm. The circulation channel 17 includes the cooler 18, and the biodegradable plastic B can be finely pulverized while being cooled by the cooler 18. More preferably, as shown in FIG. 1, the crushed plastic particles D are decomposed with alkali K and then mixed with the organic slurry S. It is desirable that the alkali K be ammonia.
[0015]
  Referring also to the embodiment of FIG. 1, the biodegradable plastic processing system of the present invention includes a bioreactor 9 (see FIG. 4) having a reaction chamber 10 in which a carrier 12 to which methane fermentation microorganisms are attached is held. Degradable plastic BWet pulverizer with liquid injection 16 Circulating channel containing 17 (See Fig. 2)A pulverizer 3 for finely pulverizing plastic particles D into the reaction chamber 10, a slurry tank 7 for storing the garbage-like organic slurry S and communicating with the reaction chamber 10, and a composition suitable for methane fermentation of the plastic particles D and the organic slurry S Is provided with mixing means 8 for mixing.
[0016]
  Preferably, as shown in FIG. 2, a pulverizer 3 is filled with a liquid tank 15 for injecting into the biodegradable plastic B, a wet pulverizer 16 with a transport function communicating with the liquid tank 15 and pulverizing the plastic B in the liquid. A circulation channel 17 connected to the outlet of the crusher 16 via a switching valve device 19 and communicating with the liquid tank 15 is provided.IncludeThe A cooler 18 can be provided in the circulation channel 17. More preferably, as shown in FIG. 1, a decomposition tank 4 for decomposing plastic particles D with alkali K is provided between the pulverizer 3 and the mixing means 8.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows that garbage-like waste A mixed with biodegradable plastic B is separated into biodegradable plastic B and garbage-like organic substance C, and the separated biodegradable plastic B is pulverized and separated. Figure 2 shows a schematic flow diagram of one embodiment of the present invention for treatment with garbage-like organic matter C. However, the biodegradable plastic B to be treated according to the present invention is not limited to the contaminants in the garbage-like waste A, but containers, tableware, and interiors made of biodegradable plastic discharged from various sources. Materials, home appliances, and the like can be processed. The feature of the present invention is that the biodegradable plastic B is pulverized into plastic particles D and then subjected to anaerobic fermentation treatment as a mixed slurry M with the garbage-like organic slurry S.
[0018]
FIG. 4 shows an example of a bioreactor 9 used in the present invention. The illustrated bioreactor 9 includes a reaction chamber 10 filled with a microbial carrier 12 to which methane fermentation microorganisms are attached, and a heat retaining means 11 for maintaining the reaction chamber 10 at the activation temperature of the methane fermentation microorganisms. As the methane fermentation microorganism, it is desirable to use a thermophilic bacterium that exhibits activity at a relatively high temperature (50 to 60 ° C.). Thermophilic bacteria are more active than mesophilic methanogens that are active at medium temperatures (35-38 ° C), and are suitable for treatment of persistent organic substances such as biodegradable plastic B and garbage-like organic substances C. Yes. As shown in FIG. 5, an example of the microorganism carrier 12 is one in which a hollow cylinder 12a having a porous peripheral wall 12b made of a nonwoven fabric made of glass fiber or carbon fiber is held in a frame body 12c. The carrier 12 in the illustrated example can be manufactured at a relatively low cost, and the inner diameter of the hollow cylinder 12a can be adjusted to avoid clogging with solid matter. In addition, a relatively wide gap between fibers can be secured by making the nonwoven fabric relatively light in unit weight, and high-temperature bacteria can adhere to the gap at a high density, so there are many solids and high-concentration mixing. It is possible to decompose the slurry M efficiently. For example, the hollow cylindrical microbial carrier 12 shown in FIG. 5 is regularly packed in the reaction chamber 10 to form a fixed bed.
[0019]
The reaction chamber 10 of the illustrated bioreactor 9 is maintained at a temperature 50 to 60 ° C., preferably 54 to 56 ° C., most suitable for the activity of thermophilic bacteria by the heat retaining means 11. The energy required for the heat retaining means 11 can be covered by energy conversion of the biogas G generated in the bioreactor 9. In the illustrated example, a heat exchanger provided in a circulation path that circulates the mixed slurry M in the reaction chamber 10 through the outside of the reaction chamber 10 is used as the heat retaining means 11, and heat exchange is performed on, for example, high-temperature water from the energy recovery device 14 described later. By sending it to the vessel, the reaction chamber 10 is maintained at the active temperature of the high-temperature bacteria. The energy (for example, electric power) from the energy recovery device 14 can be used for the power of the circulation pump 11a for circulating the mixed slurry M.
[0020]
As shown in FIG. 1, a slurry S of garbage-like organic matter C is stored in a slurry tank 7 communicating with a reaction chamber 10 of a bioreactor 9. The garbage-like organic substance C is finely pulverized by a fine pulverizer 6 to a particle size of about 1 mm, preferably about several hundred microns on average. The pulverized garbage-like organic substance C is directly or mixed with the dilution water W of an equivalent amount or about 2 times, is made into a slurry, and is temporarily stored in the slurry tank 7. When the nitrogen concentration or fat concentration of the garbage-like organic substance C is high, the dilution water W can be diluted to an appropriate concentration by increasing the amount of the dilution water W. In the present invention, however, the dilution water W is considered in consideration of mixing with the biodegradable plastic B described later. It is desirable to adjust the amount of nitrogen and the nitrogen concentration of the slurry S. In addition, from the viewpoint of downsizing the bioreactor 9 and increasing the efficiency of biogas generation, it is desirable that the dilution water W is not so much, and the organic substance concentration of the organic slurry S is about 100 to 300,000 mg / L in terms of CODcr value. It is good to do.
[0021]
As shown in FIG. 1, the biodegradable plastic B is finely pulverized into plastic particles D by the pulverizer 3 and led to the bioreactor 9. By finely pulverizing, the surface area of the biodegradable plastic B can be increased and easily dissolved in water to facilitate and speed up the decomposition by the methane fermentation microorganism. Conventionally, it has been proposed to increase the decomposition rate by pulverizing the biodegradable plastic B, but the present inventor considered that the biodegradable plastic B has the same size as the garbage-like organic slurry S, for example, the average particle size. It is found that the mixed slurry M can be processed in about the same time as the conventional garbage-like organic slurry S alone by finely pulverizing it into a plastic particle D of about 1 mm and mixing it with the garbage-like organic slurry S. It was.
[0022]
FIG. 2 shows an example of a pulverizer 3 that can finely pulverize the biodegradable plastic B into plastic particles D having an average particle size of about 1 mm. The crushing device 3 in the illustrated example includes a liquid tank 15 for injecting and mixing water W into the biodegradable plastic B, a wet crusher 16 communicating with the liquid tank 15, and a switching valve device 19 at the outlet of the crusher 16. And a circulation channel 17 that is connected to the liquid tank 15 and communicates with the liquid tank 15. The valve V2 of the switching valve device 19 is closed and the valve V1 is opened, and the biodegradable plastic B is put into the liquid tank 15, and the biodegradable plastic B is pulverized to the required particle size together with the water W until wet. 16 and the circulation flow path 17 are refluxed, and the valve V1 of the switching valve device 19 is closed and the valve V2 is opened to take out the plastic particles D finely pulverized to the required particle size. The wet pulverizer 16 in the illustrated example has a transport function, and the biodegradable plastic B and water W in the liquid tank 15 are circulated by the wet pulverizer 16, but if necessary, a circulation pump separately from the pulverizer 16 May be provided. Note that, instead of the water W, the biodegradable plastic B can be mixed with the alkali K and pulverized by the pulverizing apparatus 3 shown in the drawing as will be described later. In this case, the crushing device 3 and the decomposition tank 4 can be integrated in FIG.
[0023]
FIG. 3 shows an example of a wet type pulverizer 16 with a pump type transport function. The wet pulverizer 16 in the illustrated example includes an inlet 20 and an outlet 26, an axial-flow type crushing impeller 22 fixed to a rotating shaft 27 and having a blade formed at an edge portion, and the inlet 20 side of the impeller 22 A cutter 21 opposed to the impeller 22 via a minute gap, an annular blade 23 opposed to the peripheral edge of the impeller 22 via a minute gap, and a slit 24 opposed to the discharge port 26 side of the impeller 22 via a minute gap, And a pressure-feeding impeller 25 fixed to a rotary shaft 27 between the slit 24 and the discharge port 26. The biodegradable plastic B introduced into the intake 20 is rough-cut between the cutter 21 and the edge of the crushing impeller 22 that rotates, and is stirred and fed by the axial crushing impeller 22. At this time, a part of the biodegradable plastic B is pumped by a centrifugal force in a direction perpendicular to the rotating shaft 27 and hits the annular blade 23 to be cut. Further, the biodegradable plastic B that has passed through the crushing impeller 22 is further crushed between the impeller 22 and the slit 24. The biodegradable plastic B that has passed through the screen-like eyes of the slit 24 is pumped to the discharge port 26 by the impeller 25. The present inventor averaged the biodegradable plastic B by circulating the biodegradable plastic film-like bags, containers, dishes, etc. with the water W using a wet crusher 16 having a slit 24 of about 3 mm. It was confirmed that it could be finely pulverized into plastic particles D having a particle size of about 1 mm.
[0024]
The biodegradable plastic B can be dissolved by frictional heat at the time of pulverization. However, the biodegradable plastic B itself can be obtained by mixing the biodegradable plastic B and the water W and finely pulverizing the sensible heat of the water W. It is possible to prevent dissolution by suppressing the temperature rise. Further, even when the biodegradable plastic B is somewhat dissolved, it is possible to prevent the melt from adhering to the cutter 21, the impeller 22, and the annular blade 23, and blocking the screen-like eyes of the slit 24. The amount of water W to be mixed with the biodegradable plastic B can be appropriately selected in consideration of the ease of flow of the circulation channel 17 (ease of transportation), but if the amount of water W cannot be increased too much, As shown in FIG. 2, the cooler 18 may be provided in the circulation channel 17 to cool the biodegradable plastic B and the water W indirectly. An example of the cooler 18 in the illustrated example is a heat exchanger. For example, it is possible to provide a temperature sensor (not shown) in the circulation channel 17 and additionally operate the cooler 18 when the temperature rises.
[0025]
As shown in FIG. 1, when the biodegradable plastic B to be processed is large, the coarse pulverizer 2 for roughly pulverizing the biodegradable plastic B into a size that can be charged into the wet pulverizer 16 is used as the pulverizer 3. Can be included. For example, a biaxial cutter or the like belonging to the prior art can be used as the coarse pulverizer 2, and the biodegradable plastic B is roughly pulverized to, for example, about 10 to 20 mm, and then charged into the wet pulverizer 16. Energy is required for pulverization of the biodegradable plastic B by the coarse pulverizer 2 and the pulverizer 3. In the present invention, energy (for example, electric power) required for pulverization is provided by energy conversion of the biogas G generated in the bioreactor 9. It is possible.
[0026]
The plastic particles D discharged from the pulverizer 3 are mixed with the organic slurry S stored in the slurry tank 7 and charged into the reaction chamber 10 of the bioreactor 9 as a mixed slurry M having a composition suitable for methane fermentation. In FIG. 1, a mixing tank is provided as a mixing means 8 for mixing the plastic particles D and the organic slurry S, and the composition of the mixed slurry M is adjusted in the mixing tank. However, the mixing means 8 is not limited to the illustrated example. For example, the flow rate for adjusting the introduction amount of the organic slurry S from the slurry tank 7 to the reaction chamber 10 based on the discharge amount of the plastic particles D from the pulverizer 3 to the reaction chamber 10. An adjusting device or the like may be used as the mixing means 8 to adjust the composition of the mixed slurry M in the reaction chamber 10.
[0027]
80 to 90% of the organic matter in the mixed slurry M is decomposed by the methane fermentation microorganisms in the reaction chamber 10 of the bioreactor 9 to become biogas G and residual liquid F. The composition of biogas G is methane (CH_Four) Average 60-65%, carbon dioxide (CO₂) Is 35 to 40% and hydrogen sulfide is about several hundred ppm. Preferably, the biogas G generated in the bioreactor 9 is sent to the energy recovery device 14 and converted into energy. An example of the energy recovery device 14 is a fuel cell or a gas engine power generator. In addition, the residual liquid F generated in the bioreactor 9 is sent to the secondary treatment facility 13, and the treated water that has been highly treated in the secondary treatment facility 13 is discharged into sewers and rivers, and the residual organic matter can be recovered as compost material. .
[0028]
For example, when the garbage-like organic slurry S with a CODcr value of about 300,000 mg / L is decomposed by thermophilic bacteria, 130 m^ThreeBiogas of about / t is generated. The CODcr value of the plastic grain D is about 1.3 million mg / kg.^ThreeBiogas of about / t is generated. That is, in the present invention in which the mixed slurry M of the plastic particles D and the organic slurry S is anaerobically decomposed with methane fermentation microorganisms, theoretically 4 to 5 times or more biobiochemically compared with the conventional anaerobic decomposition of only the organic slurry S. The gas G is considered to be generated, and the energy recovery device 14 can be expected to recover more energy than the energy consumption of the entire system of FIG. The dotted line arrows in FIG. 1 indicate energy supply lines from the energy recovery device 14 to each device of the system of the present invention. Further, in the present invention, the additives that may be contained in the biodegradable plastic B remain in the residual liquid F and are diluted and discharged together with water in the secondary treatment facility 13, so that the additives and the like are concentrated. Is less likely to occur.
[0029]
Thus, it is possible to provide the “processing method and system capable of efficiently decomposing biodegradable plastics with less energy consumption”, which is an object of the present invention.
[0030]
Preferably, as shown in FIG. 1, a decomposition tank 4 for decomposing plastic particles D with alkali K is provided between the pulverizer 3 and the mixing means 8, and the plastic particles D finely pulverized by the pulverizer 3 are converted with alkali K. After decomposing, it is mixed with the organic slurry S. For example, the alkaline solution is stored in the decomposition tank 4 and the plastic particles D are immersed in the decomposition tank 4 for a required time. As disclosed in Patent Documents 4 to 6, it is conventionally known that biodegradable plastic B can be decomposed by contact with alkali K. Patent Document 6 states that the polymer of biodegradable plastic B is decomposed into monomers or oligomers by contact with an alkaline treatment liquid (paragraphs 0053 to 0061 of Patent Document 6). The methane-fermenting microorganism used in the present invention first decomposes the molecular chain of the surface layer of the polymer substance into low molecules by the hydrolysis reaction using the extracellular degrading enzyme. By promoting the hydrolysis reaction, the plastic particles D can be easily dissolved in the aqueous solution, and the fermentation in the bioreactor 9 can be further promoted.
[0031]
The type and pH of the alkali K can be appropriately selected according to the type of the biodegradable plastic B, etc. However, the present inventor has found that it is effective to increase the pH to 13 or more when the alkali K is ammonia. It was. Further, by using ammonia as the alkali K, the shortage of the nitrogen component in the biodegradable plastic B described above is compensated, the balance between the carbon component and the nitrogen component in the plastic particle D is made suitable for anaerobic fermentation, and the organic slurry S and The composition adjustment at the time of mixing can be facilitated. If necessary, the energy (for example, high-temperature water) recovered by the energy recovery device 14 is added to the decomposition tank 4 to raise the temperature of the alkali K as shown in FIG. It is also possible to accelerate the degradation.
[0032]
In the flow chart of FIG. 1, a neutralization tank 5 is provided between the decomposition tank 4 and the mixing means 8 using alkali K, and the plastic particles D after alkali decomposition are neutralized and then mixed with the organic slurry S. For example, an acid or other suitable neutralizing agent is added to the neutralization tank 5 to adjust the plastic particles D to about pH 6.5 to 8.0 which is most suitable for the activity of thermophilic bacteria. However, in the present invention, it is sufficient if the pH of the mixed slurry M obtained by mixing the organic slurry S with the plastic particles D is within the activity range of the methane fermentation microorganism, and when the mixed amount of the organic slurry S is larger than the plastic particles D, etc. Since the mixed slurry M can be adjusted to pH 8.0 or less even when the plastic particle D is pH 8.0 or more, the neutralization tank 5 is not essential for the present invention.
[0033]
【Example】
In the system of FIG. 1, the garbage-like waste A mixed with the biodegradable plastic B is separated into the plastic B and the garbage-like organic substance C, and the sorted plastic B is led to the coarse pulverizer 2 and the pulverizer 3. There is provided a sorting device 1 for guiding the sorted garbage-like organic matter C to the pulverizer 6 and the slurry tank 7. As a utilization mode of the biodegradable plastic B, it is expected to spread as garbage packaging bags / containers, and the construction of a circulation system utilizing the characteristics of the biodegradable plastic B is required. According to the system of FIG. 1, although the biodegradable plastic B is mixed, it is possible to treat the garbage-like waste A efficiently and extremely energy-saving. However, biodegradable plastic B used for garbage packaging bags / containers is often in the form of a thin film, but in order to increase energy recovery, it is made of biodegradable plastic from other sources. It is effective to process containers, tableware, interior materials, home appliances, etc. at the same time.
[0034]
6 to 9 show an example of the sorting apparatus 1 suitable for the present invention. The sorting apparatus 1 shown in the figure has an intake 46 and an intake 41 for taking in the garbage-like waste A mixed with the biodegradable plastic B in the vicinity of one end in the longitudinal direction and an outlet 48 in the other end. The horizontal cylindrical body 32, the pore group 40 formed between one end of the bottom wall 33a of the cylindrical body 32 and the discharge port 48, and the radial direction fixed to the rotary shaft 35 on the longitudinal axis inside the cylindrical body 32 A rotary blade 36 (see FIGS. 7 to 9) whose tip end faces the cylindrical bottom wall 33a with a minute gap, an intake blade 52 (see FIG. 9) attached to the rotary shaft 35 or the inlet 41 side end of the rotary blade 36 A screw conveyor which is an organic substance conveying means communicating with the air flow path 42, the pore group 40 and the slurry tank 7 (see FIG. 1) formed between the rotation region of the rotor blade 36 and the top wall 33b of the cylindrical body 32. 65. Plastic that communicates with the screw-type delivery device 66, the transport pipe 67, and the discharge port 48 with the coarse pulverizer 2 and the pulverizer 3 (see FIG. 1). Having a conveying pipe 72 and transfer apparatus 74 is a feed means.
[0035]
The cylindrical body 32 in the illustrated example is formed by connecting a bottom wall 33a having a lower half portion with an arc-shaped cross section and a top wall 33b having an upper half portion having an elliptical shape with the cross section bulging outward in the radial direction. It is a type. As shown in FIG. 7, a rotating shaft 35 is provided along the longitudinal axis inside the cylinder 32, in the illustrated example, the central axis of the arc-shaped bottom wall 33 a, and the tip of the rotor blade 36 fixed to the rotating shaft 35 and the arc-shaped bottom The organic material C in the garbage-like waste A can be finely pulverized to such an extent that it can be discharged from the pore group 40 of the arc-shaped bottom wall 33a when the rotor blades 36 are rotated. As shown in FIG. 9, a resilient plate 38 such as a rubber plate may be attached to the tip of the rotary blade 36. Further, by forming the top wall 33b of the cylindrical body 32 into an elliptical shape bulging outward, an air flow path 42 extending in the longitudinal direction of the cylindrical body 32 is formed between the rotation region of the rotary blade 36 and the top wall 33b. The plastic B in the garbage-like waste A can be sent to the discharge port 48 side through the air flow path 42. Further, as shown in FIG. 8, an intake vane 52 (see also FIG. 9) is attached to the end of the rotary shaft 35 or the rotary blade 36 on the intake port 41 side at a required air reception angle δ. The air intake blade 52 can take in the air flow R from the air intake 41 according to the principle of an electric fan when rotating.
[0036]
The intake 46 of the cylinder 32 is preferably provided in a direction that intersects with the rotation shaft 35. For example, the intake 46 is provided so as to be shifted from the portion directly above the rotation shaft 35 of the cylinder top wall 33b in the rotation direction of the rotor blade 36 (direction indicated by arrow E in FIG. 7). The discharge port 48 is preferably provided in the bottom wall 33a at the other end of the cylindrical body 32. By providing as wide a discharge port 48 as possible on the cylindrical bottom wall 33a, the plastic B can be efficiently discharged from the discharge port 48 using not only the air flow R but also the dropping action by gravity. An organic hopper 64 is hermetically joined below the bottom wall 33a of the cylindrical body 32 in which the pore groups 40 are provided, and a hopper 71 that temporarily stores plastic B is hermetically joined below the discharge port 48.
[0037]
The sorting device 1 in the illustrated example connects the rotary shaft 35 to an appropriate drive device (for example, an electric motor) 39 by a belt 53 or the like (see FIG. 6), and the rotary shaft 35 is 500 to 600 per minute in the direction indicated by the arrow E. Garbage-like waste A is introduced through the intake 46 while rotating at a rotation speed of about the rotation speed. As shown in FIG. 8, when the intake blade 52 rotates together with the rotation shaft 35, air is sucked from the intake port 41 to the inside of the cylinder 32, and the air flow R flowing from the intake port 41 to the discharge port 48 in the cylinder 32. Is formed. Garbage-like waste A introduced into the cylinder 32 through the intake 46 is agitated and crushed by the rotating blades 36 that rotate together with the rotating shaft 35 and separated into plastic B and organic matter C. The separated plastic B is sent to the discharge port 48 side by the air flow R, and falls from the discharge port 48 to the hopper 71 by the air flow R and gravity. On the other hand, the organic substance C falls on the bottom wall 33a of the cylindrical body 32, and is further finely pulverized into a slurry at a minute gap between the tip of the rotor blade 36 and the bottom wall 33a, and passes from the pore group 40 to the organic substance hopper 64. Fall. In FIG. 8, the flow of the organic substance C is indicated by a white arrow, the flow of the plastic B is indicated by a black arrow, and the flow of air is indicated by an arrow with a black triangle.
[0038]
The organic matter hopper 64 in the illustrated example has a screw conveyor 65 attached hermetically at the lower part, and a screw type delivery device 66 is airtightly connected to the outlet of the conveyor 65. The pulverizer 6 and the slurry tank 7 (FIG. 1) are connected to the delivery device 66. The transport pipe 67 leading to (see) is connected. The organic substance C that has fallen on the organic substance hopper 64 is sent to the screw-type delivery device 66 by the screw conveyor 65, and sent to the pulverizer 6 and the slurry tank 7 through the delivery device 66 and the transport pipe 67, and the processing system of the present invention. To be served. The conveyor 65, the delivery device 66, and the transport pipe 67 in the illustrated example constitute an organic substance transport unit.
[0039]
In addition, an outside air-blocking hermetic transfer device 74 is hermetically coupled to the lower part of the plastic B hopper 71, and a transfer pipe 72 is connected to the transfer device 74. The plastic B in the hopper 71 is transported to the coarse pulverizer 2 and the pulverizer 3 via the transport pipe 72 while avoiding contact with the outside air by the transport device 74, and provided to the processing system of the present invention. As shown in FIG. 7B, an example of the hermetic transfer device 74 includes a chain 74a in which a plurality of partition plates 74b are fixed at appropriate intervals inside a transfer pipe 72 (72a, 72b). , 72b is a mechanism for scraping out the plastic B loaded between the partition plates 74b by driving the chain 74a with a drive mechanism 73 (see FIG. 6). The conveying device 74 and the conveying pipe 72 in the illustrated example constitute a plastic conveying means.
[0040]
A plurality of air guide plates 45 that guide the air flow R in the air flow path 42 in a direction intersecting the rotation shaft 35 are attached to the top wall 33b of the cylindrical body 32, and the air flow depends on the number and direction of the air guide plates 45. It is desirable to be able to adjust the R residence time in the cylinder. For the light organic substance C that is difficult to separate from the plastic B, the prevention of a short pass can be expected by increasing the residence time. Further, it is desirable to install a quantitative supply crusher 54 that quantitatively takes in the garbage-like waste A at the intake 46. Various types of fixed-feed crusher 54 can be used, but those that can easily cope with clogging of garbage-like waste A or temporary stop due to abnormal torque are desirable.
[0041]
Preferably, as shown in the figure, an exhaust port 62 is provided in the plastic B hopper 71 (see FIG. 7B), and the exhaust port 62 and the intake port 41 of the cylindrical body 32 are connected to the outside of the cylindrical body 32 by a vent pipe 63. Communicate in an airtight manner. Since the separation apparatus 1 comes into contact with the waste A and the air flow R containing a considerable odor is discharged from the discharge port 48 together with the plastic B, it is necessary to take measures against the surrounding odors. Most of the air sent to the hopper 71 is returned to the cylinder 32 through the exhaust port 62, the vent tube 63, and the intake port 41 by the suction action of the intake vanes 52 and circulated through the vent pipe 63. Therefore, the odor can be substantially confined in the device 1.
[0042]
According to the sorting apparatus 1 in the illustrated example, it is possible to continuously and efficiently sort bagged business garbage-like waste A discharged from a large-scale commercial facility or the like. Therefore, if the processing system of the present invention is constructed as shown in FIG. 10 using the sorting apparatus 1, continuous and efficient processing of the garbage-like waste A mixed with the biodegradable plastic B becomes possible. . Further, as shown in FIG. 1, the present invention can provide energy used in the separation apparatus 1 by energy conversion of the biogas G generated in the bioreactor 9, and a system that consumes very little energy as a whole is constructed. it can. For this reason, the system of the present invention can be expected to contribute to expanding the use of the biodegradable plastic B as a garbage packaging bag / container.
[0043]
【The invention's effect】
  As described above, the biodegradable plastic processing method and system according to the present invention uses a biodegradable plastic.By injecting and circulating in a circulation channel containing a wet pulverizerThe pulverized plastic is mixed with the waste-like organic matter slurry and brought into contact with the methane-fermenting microorganism, and the biodegradable plastic is treated with methane-fermented organic matter in the presence of the waste-like organic matter. There is an effect.
[0044]
(B) Since the biodegradable plastic is subjected to anaerobic fermentation treatment, energy for aeration is unnecessary, and conversely, a large amount of energy can be recovered from biogas.
(B) Since the biodegradable plastic is finely pulverized and then mixed with the garbage-like organic substance slurry for processing, the plastic can be processed in a time as short as the garbage-like organic substance.
(C) Since biodegradable plastics can be processed in a short time, the bioreactor can be miniaturized, the entire system can be made compact, and construction costs can be reduced.
(D) Since the additive added to the biodegradable plastic is diluted with water and discharged, there is little risk of the additive being concentrated.
(E) It can be combined with a conventional garbage-like waste anaerobic treatment facility relatively easily, and an increase in the amount of biogas generated can be expected by adding a biodegradable plastic treatment function.
(F) Compared to conventional anaerobic decomposition of only garbage-like organic matter, the generation of biogas is theoretically expected to be 4 to 5 times or more, so use as a power generation facility can also be expected.
(G) Combining with a garbage sorting device that contains biodegradable plastics can be expected to contribute to expanding the use of biodegradable plastics as garbage packaging bags and containers.
[Brief description of the drawings]
FIG. 1 is a schematic flow diagram of one embodiment of the present invention.
FIG. 2 is an explanatory diagram of an example of a crusher shown in FIG.
FIG. 3 is an explanatory diagram of an example of a wet pulverizer shown in FIG. 2;
FIG. 4 is an explanatory diagram of an example of the bioreactor shown in FIG.
FIG. 5 is an explanatory diagram of an example of a microbial carrier held in a bioreactor.
FIG. 6 is an explanatory diagram of an example of the sorting device in FIG. 1;
FIGS. 7A and 7B are a front view and a rear view of the separation device of FIG.
FIG. 8 is a schematic side view showing the sorting action of the sorting apparatus of FIG. 6;
FIG. 9 is an explanatory diagram of a rotor blade and an intake blade of the sorting device of FIG.
10 is an explanatory view of another embodiment of the present invention using the sorting apparatus of FIG.
[Explanation of symbols]
1 ... Sorting device 2 ... Coarse grinder
3 ... Crusher 4 ... Decomposition tank
5 ... Neutralization tank 6 ... Fine grinding machine
7 ... Slurry tank 8 ... Mixing means
9 ... Bioreactor 10 ... Reaction chamber
11 ... Heat retention means 11a ... Circulating pump
12 ... Microorganism carrier 12a ... Hollow cylinder
12b ... Porous peripheral wall 12c ... Frame
13 ... Secondary treatment facility 14 ... Energy recovery equipment
15 ... Liquid tank 16 ... Wet grinding machine
16a ... Driving means 17 ... Circulation channel
18 ... Cooler (heat exchanger) 19 ... Switch valve device
20 ... Intake 21 ... Cutter
22 ... Fracture impeller 23 ... Ring blade
24 ... Slit 25 ... Pressure impeller
26 ... Discharge port 27 ... Rotating shaft
32 ... Cylinder (drum) 33 ... Surrounding wall
33a… Bottom wall 33b… Top wall
34 ... Leg 35 ... Rotating shaft
35a ... Bearing 36 ... Rotary blade (plate blade)
37 ... Tip edge of rotor blade 38 ... Resilient plate
39 ... Drive device 40 ... Pole group
41… Inlet 41a… Inlet connection
41b… Intake duct 42… Air flow path
43 ... Supply hopper 44 ... Airflow guide
45 ... Baffle plate 46 ... Inlet
47… Intake duct 48… Discharge port
49 ... Exhaust duct 50 ... Cutter fin member
51 ... Sawtooth edge 52 ... Inlet blade
53… Belt 54… Quantitative supply crusher
55 ... Rotary shaft 56 ... Drive device
58 ... Water nozzle
62 ... Exhaust port 62b ... Exhaust duct
63 ... Vent pipe 64 ... Organic hopper
65 ... Screw conveyor
66… Screw delivery device 67… Transport pipe
70… Exhaust outlet strainer
71 ... Hopper 72, 72a, 72b ... Conveying pipe
73 ... drive mechanism 74 ... (sealed) conveyor
74a ... Chain 74b ... Partition plate
80… Waste transport vehicle 81… Waste storage tank
82 ... Screw conveyor
A ... Garbage-like waste mixed with biodegradable plastic
B ... Biodegradable plastic C ... Garbage-like organic matter
D ... Plastic grain E ... Rotation direction of rotor blade
F ... Residual liquid G ... Biogas
K ... alkali M ... mixed slurry
R ... Air flow S ... Garbage like organic slurry
W ... (dilution) water Y ... cooling water
V1, V2 ... Valve

Claims (19)

The biodegradable plastic is injected and pulverized by circulating it in a circulation channel including a wet pulverizer , and the pulverized plastic is mixed with a slurry of garbage-like organic matter and brought into contact with methane fermentation microorganisms. A method for treating biodegradable plastics, which is produced by subjecting plastics to methane fermentation in the presence of garbage-like organic matter. The processing method of Claim 1 WHEREIN: The processing method of the biodegradable plastic formed by mixing the plastic after the said grinding | pulverization and the said organic substance slurry in the composition suitable for methane fermentation. 3. The disposal method according to claim 1 or 2, wherein the biodegradable plastic is used as a contaminant in the garbage-like waste, and the plastic separated from the garbage-like waste is pulverized to separate the garbage-like waste after separation. A method for treating biodegradable plastics, which is mixed with an organic slurry in a product. The processing method according to any one of claims 1 to 3 , wherein a cooling device is included in the circulation channel, and the biodegradable plastic is finely pulverized while being cooled by the cooling device. 5. The processing method according to claim 1, wherein the biodegradable plastic is pulverized into plastic particles having an average particle size of about 1 mm. 6. The processing method according to claim 1 , wherein the pulverized plastic is decomposed with an alkali and then mixed with the organic slurry. The processing method of Claim 6 WHEREIN: The processing method of the biodegradable plastic which uses the said alkali as ammonia. The processing method according to claim 6 or 7 , wherein the plastic after alkali decomposition is neutralized and then mixed with the organic slurry. The processing method according to any one of claims 1 to 8 , wherein the biodegradable plastic is provided with energy for finely pulverizing the biodegradable plastic by energy conversion of biogas generated during the methane fermentation. A bioreactor having a reaction chamber in which a carrier to which methane fermentation microorganisms are attached is held. The reaction is performed by injecting biodegradable plastic and circulating it in a circulation channel including a wet pulverizer to pulverize it into plastic particles. A biodegradable plastic comprising a pulverizing apparatus for guiding to a chamber, a slurry tank for storing a garbage-like organic substance slurry and communicating with the reaction chamber, and a mixing means for mixing the plastic particles and the organic slurry into a composition suitable for methane fermentation Processing system. 11. The system according to claim 10 , wherein a liquid tank for injecting the biodegradable plastic into the pulverizer, a wet pulverizer with a transport function for pulverizing the plastic in the liquid, and an outlet of the pulverizer. A biodegradable plastic processing system including a circulation channel connected to the liquid tank through a switching valve device. 12. The biodegradable plastic processing system according to claim 11 , wherein a cooling device is provided in the circulation channel. 13. The biodegradable plastic processing system according to claim 10 , wherein the pulverizing apparatus includes a coarse pulverizer that roughly pulverizes the biodegradable plastic into a size that can be charged into the wet pulverizer. . The biodegradable plastic processing system according to any one of claims 10 to 13 , wherein a decomposition tank for decomposing plastic particles with an alkali is provided between the pulverizer and the mixing means. The system of Claim 14 WHEREIN: The processing system of the biodegradable plastic which uses the said alkali as ammonia. 16. The biodegradable plastic treatment system according to claim 14 , wherein a neutralization tank for neutralizing the plastic particles after the alkali decomposition is provided between the decomposition tank and the mixing means. 17. The system according to claim 10, wherein the garbage-like waste mixed with the biodegradable plastic is separated into plastic and garbage-like organic matter, and the separated plastic and organic matter are led to the pulverizer and the slurry tank. A biodegradable plastic processing system equipped with a sorting device. 18. The system according to claim 17 , wherein an intake port and an intake port for taking in garbage-like waste mixed with biodegradable plastic are opened near one end in the longitudinal direction and an exhaust port is formed at the other end. A horizontal cylinder, a group of pores drilled between one end of the cylinder bottom wall and the discharge port, fixed to the rotation axis on the longitudinal axis inside the cylinder, and the radial protrusion has a minute gap in the cylinder bottom wall. The rotor blades opposed to each other, the intake shaft attached to the rotary shaft or the intake port side end of the rotor blades, the air flow path formed between the rotation region of the rotor blades and the top wall of the cylindrical body, the pore group and the slurry A biodegradable plastic processing system comprising organic material conveying means communicating with a tank and plastic conveying means communicating with the discharge port and the coarse pulverizer or pulverizer. 19. The system according to claim 10 , further comprising an energy recovery device that recovers the biogas generated in the bioreactor, converts the biogas into energy, and supplies the energy to the coarse pulverizer and / or the pulverizer. A biodegradable plastic processing system.

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