JP6369694B2 - Method for reducing molecular weight of organic substance and facility for reducing molecular weight - Google Patents

Description

  The present invention relates to a technique for modifying an organic substance to reduce its molecular weight in order to convert the organic substance such as plastic into a gaseous fuel or the like.

At present, most of waste plastic, oil-impregnated sludge, waste oil, etc. are incinerated. However, incineration treatment has a high environmental load such as CO ₂ generation, and there is a problem of thermal damage of the incinerator, and establishment of chemical recycling technology is required.
Among chemical recycling technologies, technologies for converting organic substances into gaseous fuels and liquid fuels have been variously studied mainly with respect to waste plastics. For example, the following proposals have been made.

  In Patent Document 1, a coke oven gas (COG) having a hydrogen concentration of 60 vol% or more, preferably 80 vol% or more and a temperature of 600 ° C or more is reacted with an organic material such as waste plastic, thereby hydrogenating the organic material with high efficiency. A method for increasing the heat of COG by decomposition and gasification is disclosed. Since the hydrogen concentration in COG becomes 60 vol% or more is limited to the end of dry distillation even in the coal dry distillation process, the method of Patent Document 1 switches the gas flow path at the end of dry distillation and contains a large amount of dust. It is necessary to supply COG having a temperature of 0 ° C. or higher to a waste plastic hydrocracking reactor. However, it is difficult to stably operate the flow path switching valve for a long time under such a severe condition, and in this sense, it can be said that the technique is poor in feasibility. Furthermore, for efficient gasification of waste plastic, it is necessary to continuously supply COG containing 60 vol% or more of hydrogen to the hydrocracking reactor. In addition, it is necessary to install a hydrogen concentration meter and a flow path switching valve, which increases the equipment cost.

  Further, Patent Document 2 discloses a method in which petroleum fluid contact catalyst (FCC) is used as a heat medium / catalyst and waste plastic is decomposed at a temperature of 350 to 500 ° C. to be converted into liquid fuel. However, in this method, although catalytic cracking and aromatization proceed by addition of FCC catalyst, since the reaction is carried out with an inert gas flow, 13% by mass of heavy oil and coke are generated (Example 1). ) However, it cannot be said that it is a satisfactory level for light fuel production technology.

Further, in Patent Document 3, when pyrolyzing RDF, wood, etc., the gas generated by pyrolysis is steam reformed, and the gas having a high hydrogen concentration by this steam reforming is circulated to the pyrolysis section to generate hydrogen. A method of performing pyrolysis in a gas atmosphere with a high concentration is disclosed. However, the gas generated by this method is mainly H ₂ , CO, CO _{2 and} has a heat of combustion of about 1800 kcal / Nm ³ which is slightly lower than that of the exhaust gas generated from the metallurgical furnace, and its value as a gaseous fuel is limited. It will be something like that.

  On the other hand, in Patent Document 4, hydrogen and carbon dioxide generated by the shift reaction are added to the shift reaction by adding excess water vapor to the exhaust gas containing carbon monoxide generated in the metallurgical furnace to cause the shift reaction. A method is disclosed in which a mixed gas containing water vapor that has not been consumed is brought into contact with an organic substance to reduce the molecular weight. This method is an excellent method capable of efficiently reducing the molecular weight of an organic substance under unprecedented mild reaction conditions of about 400 to 900 ° C. under normal pressure.

JP 2007-224206 A JP 2010-13657 A JP 2001-131560 A JP 2012-188641 A JP 2004-34534 A

  In the method of reducing the molecular weight of Patent Document 4, the organic material is supplied to the low molecular weight reactor by (1) a method in which the organic material is blown into the reactor by a carrier gas such as nitrogen, and (2) the organic material is A method of cutting out from a mechanical quantitative charging device and dropping it into the reactor is conceivable. However, in the method (1), an organic substance is likely to be clogged in the supply system, Since the carrier gas is also introduced into the low molecular weight reactor, problems such as a decrease in the amount of heat of the product gas tend to occur. Further, in the method (2), since the inside of the low molecular weight reactor is in a pressurized state, gas leakage in which the gas in the reactor flows backward to the quantitative charging device side is likely to occur.

Regarding the problem that the amount of heat of the product gas is reduced in the method (1), for example, Patent Document 5 discloses a method in which the product gas obtained by gasification is used as a carrier gas for waste plastic that is a gasification raw material. Is disclosed. However, although this method has an advantage that the calorific value of the generated gas is higher than when nitrogen is used as the carrier gas for waste plastic, the generated gas used for the carrier gas is a gasifying agent (oxygen, water vapor, air 1). There is a problem that the yield of the product gas is reduced.
Further, in the method of Patent Document 4, since a heat source is required for the molecular weight reduction reaction, it is necessary to supply heat from the outside, and the energy cost is increased accordingly.

Therefore, the object of the present invention is to solve the above-mentioned problems of the prior art, and to efficiently reduce the molecular weight of the organic substance to obtain a high-quality, high-calorie modified product. Stable operation is possible without causing clogging troubles and gas leaks, and low molecular weight can be achieved by reforming organic substances without lowering the calorific value of the generated gas or lowering the gas yield. It is to provide a molecularization method and equipment.
In addition to the above points, another object of the present invention is to provide a method and facility for reducing the molecular weight of an organic substance that can be carried out at a low energy cost.

As a result of repeated investigations to solve the problems of the prior art as described above, the present inventors formed an organic material as a raw material into a granular shape, which was blown with a carrier gas or dropped from a quantitative charging device. Injecting into the low molecular weight reactor by charging, and using a part of the mixed gas (g) as carrier gas or seal gas for the quantitative charging device at that time, clogging in the supply system It has been found that organic molecules can be made low molecular weight without causing trouble and gas leakage, and without causing a decrease in the calorific value of the generated gas and a decrease in gas yield.
In addition, in response to the problem of reducing the molecular weight of organic substances at low energy costs, the liquid product (oily substance) generated in the low molecular weight system is separated and recovered and burned to reduce the combustion heat. We have created a new solution that can be used as a heat source for molecularization reactions.

That is, this invention makes the following a summary.
[1] By adding excess water vapor to a gas (g ₀ ) containing carbon monoxide to cause a shift reaction, hydrogen and carbon dioxide generated by the shift reaction, water vapor not consumed in the shift reaction, In which a mixed gas (g) is brought into contact with an organic substance in a low molecular weight reactor and the organic substance is modified to reduce the molecular weight. Is introduced into the low molecular weight reactor by blowing with carrier gas or dropping from the quantitative charging device, a part of the mixed gas (g) is sealed gas of the carrier gas or the quantitative charging device. A method for reducing the molecular weight of an organic substance, characterized by being used as:
[2] In the method for reducing molecular weight according to [1], the gas (g ₀ ) containing carbon monoxide has a carbon monoxide concentration of 5 vol% or more and a nitrogen concentration of 60 vol% or less. A method for reducing the molecular weight of a substance.

[3] In the method for reducing molecular weight according to [2], the gas (g ₀ ) containing carbon monoxide has a carbon monoxide concentration of 10 vol% or more and a nitrogen concentration of 55 vol% or less. A method for reducing the molecular weight of a substance.
[4] In the method for reducing molecular weight according to any one of [1] to [3] above, the liquid product (p _L ) generated by the molecular weight reduction reaction by reforming the organic substance is burned in a combustion furnace, and the combustion A method for reducing the molecular weight of an organic substance, characterized in that heat for supplying a molecular weight reduction reaction is supplied to a molecular weight reduction reactor with heat.
In the low molecular weight The method of [5] above [4], by indirectly heating the inside of the low molecular weight reactor the combustion gases of a liquid product (p _L), the combustion heat of the liquid product (p _L) A method for reducing the molecular weight of an organic substance, characterized by supplying a low molecular weight reaction heat to a low molecular weight reactor.

[6] In the molecular weight reduction method of the above [4], the molecular weight reduction reactor is a fluidized bed reactor, a part of the fluidized medium is extracted from the fluidized bed reactor, and the fluidized medium is converted into a liquid product. (P _L ) is introduced into a combustion furnace and heated with the combustion heat of the liquid product (p _L ), and the heated fluid medium is circulated through the fluidized bed reactor, thereby producing a liquid product (p _L ). A method for reducing the molecular weight of an organic substance, characterized in that the low molecular weight reaction heat is supplied to the low molecular weight reactor with the heat of combustion.
[7] The method for reducing the molecular weight of an organic substance according to the above [6], wherein the combustion furnace for the liquid product (p _L ) is a rotary kiln combustion furnace or a fluidized bed combustion furnace.
[8] In the molecular weight reduction method according to [6] or [7], the fluid medium is at least one selected from silicon oxide, aluminum oxide, magnesium oxide, iron oxide, and nickel oxide. A method for reducing the molecular weight of organic substances.

[9] By adding an excess of water vapor to a gas (g ₀ ) containing carbon monoxide to cause a shift reaction, hydrogen and carbon dioxide generated by the shift reaction, and water vapor not consumed in the shift reaction The shift reactor (1) to obtain a mixed gas (g) containing, and the mixed gas (g) obtained in the shift reactor (1) are brought into contact with an organic substance, and the organic substance is modified to reduce the molecular weight. A low molecular weight reactor (2), a gas supply pipe (3) for supplying the mixed gas (g) obtained in the shift reactor (1) to the low molecular weight reactor (2), and a granular shape. Branching from the gas supply pipe (3) and the raw material charging mechanism (4) for charging the organic material into the low molecular weight reactor (2) by blowing with carrier gas or dropping from the quantitative charging device, A part of the mixed gas (g) is used as the carrier gas or the sealing gas of the quantitative charging device. Depolymerized equipment organic substances, characterized in that it comprises a gas supply pipe for supplying the raw material charging mechanism (4) to (5).

[10] Combustion that burns the liquid product (p _L ) generated by the low molecular weight reaction by reforming the organic substance in the low molecular weight reactor (2) in the low molecular weight facility of [9] above A furnace (6) is provided, and the low molecular weight reaction heat is supplied to the low molecular weight reactor (2) by the combustion heat generated by the combustion of the liquid product (p _L ) in the combustion furnace (6). A low molecular weight facility for organic substances.
[11] The organic low-molecular equipment according to [10], further comprising an indirect heating mechanism for indirectly heating the inside of the low-molecular-weight reactor (2) with the combustion gas of the liquid product (p _L ). Equipment for reducing the molecular weight of substances.

[12] In the low molecular weight facility of [10] above, the low molecular weight reactor (2) comprises a fluidized bed reactor (2a), and a part of the fluidized medium is removed from the fluidized bed reactor (2a). withdrawn, the fluidized medium is introduced into the liquid product combustion furnace (p _L) (6), the combustion furnace (6) the liquid product in (p _L) fluidized bed the heated fluidized medium in the heat of combustion of A facility for reducing the molecular weight of an organic substance, comprising a fluid medium circulation mechanism (7) for circulation to the reactor (2a).
[13] The equipment for reducing molecular weight of an organic substance according to [12], wherein the combustion furnace for the liquid product (p _L ) is a rotary kiln combustion furnace or a fluidized bed combustion furnace.

  According to the present invention, when a high molecular weight organic substance such as waste plastic is reduced in molecular weight to be converted into gaseous fuel or liquid fuel, the organic substance is efficiently reformed to reduce the molecular weight, and the heavy component or carbon It is possible to obtain a high-calorie reformed product with low quality and containing a large amount of light components, stable operation without causing clogging troubles and gas leakage in the organic substance supply system, and product gas It is possible to reduce the molecular weight of the organic substance without causing a decrease in the amount of heat and a decrease in gas yield.

In addition, by using the combustion heat of the liquid product generated in the low molecular weight system as a heat source for the low molecular weight reaction, it is possible to reduce the molecular weight of the organic substance at a low energy cost.
Also, with regard to the equipment to be implemented, there is no need for special measuring instruments, flow path switching valves, etc., and it is possible to reduce the molecular weight of organic substances even at relatively low reaction temperatures. Can do.
In addition, since CO ₂ generated by the shift reaction is changed to CO by the carbon dioxide gas reforming reaction during the molecular weight reduction of the organic substance, chemical recycling of the organic substance can be performed without increasing the amount of generated CO _2. It becomes possible.

Explanatory drawing which shows typically one Embodiment of the low molecular weight installation of the organic substance with which this invention is implemented Explanatory drawing which shows one Embodiment of the raw material injection | throwing-in mechanism for inject | pouring an organic substance in a low molecular-weight reactor in embodiment of FIG. Explanatory drawing which shows other embodiment of the raw material injection | throwing-in mechanism for inject | pouring an organic substance in a low molecular-weight reactor in embodiment of FIG. Ring die type compression molding granulator for obtaining a molded product of an organic substance, and an explanatory diagram schematically showing the implementation status of compression molding granulation using the same Explanatory drawing which shows typically other embodiment of the low molecular weight installation of the organic substance with which this invention is implemented Explanatory drawing which shows typically other embodiment of the low molecular weight installation of the organic substance with which this invention is implemented Explanatory drawing which shows one Embodiment of the raw material injection | throwing-in mechanism for charging | throwing in an organic substance in a low molecular weight reactor in embodiment of FIG.

Low molecular method of the organic materials of the present invention, the gas (g ₀₎ containing carbon monoxide (hereinafter, referred to as "carbon monoxide-containing gas (g _0)".) Was added an excess of steam in the shift reaction (Reaction [1]) is carried out to form a mixed gas (g) containing hydrogen and carbon dioxide gas generated in the shift reaction and water vapor not consumed in the shift reaction, and the mixed gas ( g) is brought into contact with an organic substance, and the organic substance is modified to reduce the molecular weight (reaction [2]). The granular organic substance is blown with a carrier gas or from a quantitative charging device. A part of the mixed gas (g) is used as the carrier gas or the sealing gas of the quantitative charging device when the liquid is dropped into the low molecular weight reactor.
Note that adding excess water vapor to the carbon monoxide-containing gas (g ₀ ) means adding water vapor so that excess water vapor that is not consumed in the shift reaction remains in the mixed gas (g).

The above reaction [1] (shift reaction) and reaction [2] (reduction in molecular weight) are the reactions shown below.
Reaction [1]: CO + H ₂ O → H ₂ + CO ₂

In the reaction [1], excess water vapor is added to the carbon monoxide-containing gas (g ₀ ), so the mixed gas (g) after the shift reaction is excessively added with H ₂ and CO ₂ generated by the shift reaction. Minute H ₂ O will be included. Here, each concentration of water vapor, hydrogen and carbon dioxide in the gas is controlled by appropriately controlling the excess ratio of water vapor added excessively to the carbon monoxide containing gas (g ₀ ) and the reaction rate of the shift reaction. In addition, a mixed gas (g) for reducing the molecular weight of the organic substance can be obtained. The reaction rate of the shift reaction can be controlled by adjusting the residence time in the shift reactor. For example, in order to shorten the residence time, a method of shortening the shift reactor length or reducing the catalyst charge amount is common.

The gas mixture (g) for reducing the molecular weight of organic substances obtained by the shift reaction contains water vapor, hydrogen and carbon dioxide, and there are no particular restrictions on their concentrations, but decomposition of organic substances such as waste plastics. The water vapor concentration is preferably 5 to 70 vol% from the viewpoint of suppressing CO ₂ residue in the low molecular weight reaction product gas while ensuring the rate. Further, from the viewpoint of ensuring the decomposition rate of the organic substance, both the hydrogen concentration and the carbon dioxide concentration of the mixed gas (g) are preferably 5 vol% or more. From the same viewpoint, the more preferable composition of the mixed gas (g) is water vapor concentration: 20 to 70 vol%, hydrogen concentration: 10 to 40 vol%, carbon dioxide concentration: 10 to 40 vol%. In addition, it does not prevent that other gas components (for example, nitrogen etc.) are contained in this mixed gas (g).

Reaction [2] (reduction in molecular weight) is thought to involve four reactions of hydrogenation, hydrocracking, steam reforming, and carbon dioxide reforming at the same time. In addition, it is considered that the thermal decomposition reaction proceeds at the same time, the organic substance is reduced in molecular weight, and is a complex reaction in which various light hydrocarbons and carbon monoxide are generated. Here, the hydrogenation reaction includes a methanation reaction by hydrogen addition to CO or CO ₂ in addition to a hydrogen addition reaction to an unsaturated bond. In this reaction [2], the reduction of the molecular weight of the organic substance is promoted efficiently even at a relatively low reaction temperature, the hydrogen consumption is small, and the generation of heavy components and carbonaceous matter is hardly observed.

The reaction temperature at the time of lowering the molecular weight of the organic substance is preferably 400 to 900 ° C. In this temperature range, a more suitable reaction temperature may be selected according to the type of the organic substance.
The gaseous product produced by the reaction [2] is recovered and used as a gaseous fuel. In the present invention, the liquid product (p _L ) is separated from the product produced by the reaction [2], and this is used. Combustion may be performed in a combustion furnace, and the combustion heat may be used as a heat source for a reaction for reducing the molecular weight of an organic substance. This will be described in detail later.

The carbon monoxide-containing gas (g ₀ ) used for the shift reaction in the present invention preferably has a carbon monoxide concentration of 5 vol% or more and a nitrogen concentration of 60 vol% or less, and a carbon monoxide concentration of 10 vol% or more, The nitrogen concentration is particularly preferably 55 vol% or less. If the carbon monoxide concentration of the gas containing carbon monoxide (g ₀ ) is less than 5 vol%, the carbon dioxide concentration after the shift reaction will be low, and it will be low compared to hydrocarbons and carbon monoxide in the gaseous fuel after the low molecularization reaction. Hydrogen, which is a gas component of calories, tends to remain. Moreover, when nitrogen concentration exceeds 60 vol%, while the fall of LHV of gaseous fuel will become remarkable, shift reaction rate will also fall.

As the carbon monoxide-containing gas (g _0), in terms of preferred gas composition mentioned above, in particular blast furnace gas and the shaft furnace gas (typical gas composition _{CO: 10~30vol%, CO 2:} 10~30vol _{%, N 2: 55~30vol%,} H 2: 0~10vol%) are preferred. Other carbon monoxide-containing gases may be used, but those having a gas composition in the above-described preferred range are preferred. Examples thereof include exhaust gas discharged from a general combustion furnace, exhaust gas discharged from a thermal power plant, and metallurgical furnace generated exhaust gas such as converter gas. The carbon monoxide-containing gas as described above can be used as a carbon monoxide-containing gas (g ₀ ) singly or in combination of two or more.

In the present invention, there is no particular restriction on the organic material to be reduced in molecular weight by reforming, but since the organic material formed into a granular shape is charged into the low molecular weight reactor, the solid organic material is mainly used. . Among these, high molecular weight organic substances are suitable, and examples thereof include plastic (usually waste plastic), oil-containing sludge, biomass, coal, and the like, and one or more of these can be targeted. Further, a liquid organic substance such as waste oil may be mixed with one or more kinds of these solid organic substances.
In the present invention, the granular organic material is used in order to prevent clogging trouble due to the organic material in the supply system (pipe, etc.) and to smoothly supply the organic material to the low molecular weight reactor. The preferable molding conditions and molding method of the organic substance will be described in detail later.

FIG. 1 schematically shows an embodiment of a low molecular weight facility for organic substances used in the practice of the present invention, wherein 1 is a shift reaction between a carbon monoxide-containing gas (g ₀ ) and water vapor. A shift reactor 2 for obtaining a mixed gas (g), 2 is a low molecular weight reactor for reforming an organic substance with the mixed gas (g) obtained in the shift reactor 1, and 3 is a shift reactor 1. The gas supply pipe for supplying the mixed gas (g) obtained in step 1 to the molecular weight reduction reactor 2, 4 is an organic substance (organic substance formed into a granular form), blown by a carrier gas or dropped from a quantitative charging device Raw material charging mechanism 5 for charging into the molecular weight reduction reactor 2 by charging, 5 branches from the supply pipe 3, and a part of the mixed gas (g) is charged as the carrier gas or the sealing gas for the quantitative charging device. This is a gas supply pipe to be supplied to the mechanism 4.
8 is a gas scrubber for condensing a liquid product by washing the low molecular weight product generated in the low molecular weight reactor 2 with water, and 9 is a liquid from a mixture of the liquid product and water condensed in the gas scrubber 8. A separator that separates the product.

The shift reactor 1 may be a known one such as a fixed bed reactor packed with a catalyst. The supply pipe for supplying gas (gas introduced from outside the system) to the shift reactor 1 is usually a flow rate control valve capable of adjusting the supply amounts of carbon monoxide-containing gas (g ₀ ) and steam, and carbon monoxide. steam mixer for mixing the steam-containing gas (g _0), preheater for preheating the mixed gas of steam is provided with a carbon monoxide-containing gas (g _0).

The low molecular weight reactor 2 can be composed of, for example, a moving bed reactor such as an external heating rotary kiln, a fluidized bed reactor, a fixed bed reactor, or the like.
A catalyst is not particularly required for reducing the molecular weight of the organic substance in the molecular weight reduction reactor 2, but the reaction may be carried out by filling the catalyst. As the catalyst, one or more kinds of catalysts each having steam reforming activity, carbon dioxide reforming activity, hydrogenation activity, and hydrocracking activity can be used. Specific examples include Ni-based reforming catalysts, Ni-based hydrogenation catalysts, Pt / zeolite-based petroleum refining catalysts, and the like. Also, converter-generated dust, which is known to be composed of fine Fe particles, can be used as a reforming catalyst or a hydrocracking catalyst.

  The raw material input mechanism 4 includes (i) an organic substance (organic substance formed into a granular form) is injected into the low molecular weight reactor 2 by blowing with a carrier gas, and (ii) an organic substance (formed into a granular form). Organic substance) is dropped into the low molecular weight reactor 2 by dropping from a quantitative charging device, and the gas supply pipe 5 is used as a carrier gas in the case of (i) above. In the case of (ii) above, a part of the mixed gas (g) is supplied to the raw material charging mechanism 4 as the seal gas of the quantitative charging device.

  FIG. 2 shows an embodiment of the raw material charging mechanism 4 of (i) above. In the figure, 13 is a quantitative supply device for cutting out an organic substance from the raw material hopper 14, and 15 is a blowing pipe for blowing the organic substance cut out by this quantitative supply apparatus 13 into the low molecular weight reactor 2. A gas supply pipe 5 is connected in the middle, and a mixed gas (g) is supplied from the gas supply pipe 5 into the blow-in pipe 15 as a carrier gas for organic substances. In FIG. 2, the quantitative supply device 13 is configured by a screw feeder, but may be another type of device (for example, a vibration feeder, a circle feeder, or the like).

  FIG. 3 shows an embodiment of the raw material input mechanism 4 of (ii) above. In the figure, reference numeral 10 denotes a quantitative charging device that cuts out an organic substance from the raw material hopper 11 and drops it into the low molecular weight reactor 2 through the charging pipe 12 (drop charging by its own weight). A gas supply pipe 5 is connected to the raw material transfer section 100 of the quantitative charging device 10, and a mixed gas (g) is supplied as a seal gas from the gas supply pipe 5 into the raw material transfer section 100. Gas inflow from the side is sealed. The gas supply pipe 5 is connected to the end of the raw material transfer unit 100 so that the mixed gas (g) is blown toward the raw material transfer direction of the raw material transfer unit 100. The quantitative charging device 10 of the present embodiment is constituted by a screw feeder, and a gas supply pipe 5 is connected to an end of the raw material transfer unit 100 in which the transfer screw is stored.

In addition, in FIG. 3, although the fixed quantity charging device 10 is comprised with the screw feeder, the device of another type may be sufficient. For example, a vibration feeder, a circle feeder, or the like may be configured. Similarly to the embodiment of FIG. 3, the gas supply pipe 5 is connected to the raw material transfer section 100, and the gas supply pipe 5 enters the raw material transfer section 100. A mixed gas (g) is supplied as a sealing gas.
2 and 3, when the gas pressure in the gas supply pipe 5 is lower than the gas pressure in the depolymerization reactor 2, a booster is provided in the middle of the gas supply pipe 5. It is necessary to increase the gas pressure. There is no restriction on the type of the booster, and any type such as a reciprocating type or a rotary type can be used.
The type of the separator 9 is arbitrary, but since the liquid product has physical properties similar to light oil, an inclined plate method and a coalescer method are preferable.

In the operation of the facility of FIG. 1, a gas in which excess steam is added to the carbon monoxide-containing gas (g ₀ ) from outside the system (outside of the process) is supplied to the shift reactor 1 through the supply pipe, and the shift reaction is performed. . The mixed gas (g) after the shift reaction contains hydrogen and carbon dioxide generated by the shift reaction, and water vapor not consumed in the shift reaction.
The low molecular weight reactor 2 is supplied with the mixed gas (g) from the shift reactor 1 through the gas supply pipe 3 and with the organic material (organic material formed into a granular shape) from the raw material charging mechanism 4. . Further, a part of the mixed gas (g) flowing through the gas supply pipe 3 is extracted by the gas supply pipe 5 branched from the gas supply pipe 3 and supplied to the raw material input mechanism 4.

Here, in the case of the raw material charging mechanism 4 shown in FIG. 2 (raw material charging mechanism for charging an organic substance into the low molecular weight reactor 2 by blowing with a carrier gas), the organic substance in the raw material hopper 14 is quantitatively supplied. While being cut out by the apparatus 13 into the blowing pipe 15, the mixed gas (g) is supplied as a carrier gas from the gas supply pipe 5 into the blowing pipe 15, and an organic substance is blown into the low molecular weight reactor 2 by this carrier gas. .
On the other hand, in the case of the raw material charging mechanism 4 shown in FIG. 3 (raw material charging mechanism for charging an organic substance into the low molecular weight reactor 2 by dropping from the quantitative charging device), the organic in the raw material hopper 11 is used. The substance is cut out into the charging tube 12 by the quantitative charging device 10, and this organic material is dropped into the low molecular weight reactor 2 through the charging tube 12 (drop charging by its own weight). At this time, the mixed gas (g) is blown from the gas supply pipe 5 into the raw material transfer unit 100 as a seal gas. Although the inside of the low molecular weight reactor 2 is in a pressurized state, the gas inflow from the side of the low molecular weight reactor 2 (back flow of gas) is sealed by blowing the seal gas at a pressure higher than the pressure inside the reactor. Is done.

In the molecular weight reduction reactor 2, the organic material is reformed to lower the molecular weight by bringing the mixed gas (g) into contact with the organic material. Products resulting from lower molecular weight organic materials are typically gaseous products (carbon monoxide, C1-C4 hydrocarbons, etc.) and liquid products.
In the raw material charging mechanism 4, the mixed gas (g) used as the carrier gas or the seal gas as described above is introduced into the depolymerization reactor 2 together with the organic substance. This mixed gas (g) Is originally a mixed gas to be supplied to the low molecular weight reactor 2 through the gas supply pipe 3, and therefore, the heat amount of the generated gas in the low molecular weight reactor 2 and the gas yield are not basically reduced.

The reformed product (low molecular weight product) taken out from the low molecular weight reactor 2 is washed with water in the gas scrubber 8, whereby the liquid product is condensed and separated from the gas product. The mixture of liquid product and water is sent to a separator 9 to separate the water.
The gaseous product is taken out of the system through piping and used as gaseous fuel. Alternatively, since the gaseous product is a mixture of light hydrocarbons and CO, H _2, as such reducing agent for iron ore in the blast furnace, it may be utilized in steelworks.
The liquid product separated by the separator 9 is temporarily stored in a tank (not shown) and then used outside the process as an alternative to light oil or heavy oil, or burned in a combustion furnace as described later to reduce the combustion heat to a low molecular weight. Used as a heat source for the reaction.

  When the mixed gas (g) is used as the carrier gas for the organic substance in the raw material input mechanism 4 as in the embodiment of FIG. 2, the solid-gas ratio between the organic substance and the carrier gas is preferably about 0.5 to 20 kg / kg. If the solid-gas ratio is less than 0.5 kg / kg, the amount of the mixed gas (g) used with respect to the organic substance is excessive, so that the cost increases. On the other hand, when the solid-gas ratio is more than 20 kg / kg, the amount of the mixed gas (g) used with respect to the organic substance is too small, so that the trouble of blocking the organic substance in the blowing pipe 15 or the like is likely to occur.

  Further, as in the embodiment of FIG. 3, when the mixed gas (g) is used as the seal gas of the quantitative charging device in the raw material charging mechanism 4, the pressure of the mixed gas (g) for gas sealing is reduced to a low molecular weight reactor. 2 is preferably set to be higher by about 0.01 to 50 kPa than the pressure in 2. This is because when the mixed gas (g) is used as the sealing gas, the organic substance is not pneumatically transported, but the purpose is to prevent the backflow of the gas from the low molecular weight reactor 2 side. If the difference between the pressure of the mixed gas (g) for gas sealing and the pressure in the depolymerization reactor 2 is less than 0.01 kPa, the gas sealing effect may not be sufficiently obtained, while the pressure difference exceeds 50 kPa. Although there is no problem in the gas sealing effect, it is an unnecessary pressure difference and increases the cost.

Next, preferable molding conditions and a molding (granulation) method of the organic material (organic material molded into a granular shape) used as a raw material in the present invention will be described.
Although there is no special restriction | limiting in the particle size of the organic substance shape | molded in granular form, About 0.1-25 mm is preferable as a representative diameter, About 0.5-20 mm is more preferable, About 3-20 mm is especially preferable. If the representative diameter of the organic substance is less than 0.1 mm, a clogging trouble such as clogging of the organic substance in the supply system tends to occur. On the other hand, if the representative diameter of the organic substance exceeds 25 mm, the efficiency of the molecular weight reduction reaction may be reduced.
Further, the shape of the organic substance formed into a granular shape is not particularly limited, but the prismatic shape is not so preferable because it has many corners that are easily pulverized in the supply system, and the columnar shape is particularly preferable. Although there is no restriction | limiting in particular in the method of shape | molding an organic substance in such a column shape, The shaping | molding (granulation) using compression molding machines, such as a ring die type and a biaxial type, is suitable. In particular, the ring die type is often used for molding waste plastics, biomass and the like because the apparatus is inexpensive although the molding accuracy is inferior.

  FIG. 4 schematically shows a ring die type compression molding granulator and an implementation status of compression molding granulation using the same. This compression molding granulator has a die ring 16 in which a large number of die holes 160 (round holes) are provided in the entire periphery, and is rotatable inside the die ring 16 so as to be in contact with the inner peripheral surface of the die ring. A plurality of (usually 2 to 3) rolling rollers 17 disposed on the cutting edge 18 and a cutting blade 18 for cutting the molded product extruded from the die hole 160 and scraping it off from the outer peripheral surface of the die ring. Yes. The die ring 16 and the rolling roller 17 are both rotatably supported by an apparatus main body (not shown). The die ring 16 is driven to rotate by a driving device, whereas the rolling roller 17 is a non-driven free drive. The roller body rotates with the rotation of the die ring 16 due to friction with the inner peripheral surface of the die ring. Moreover, although the hole diameter of the die hole 160 is determined according to the size (diameter) of the molded product to be granulated, it is usually about 3 to 20 mm.

  In this ring die type compression molding granulator, the die ring 16 is rotationally driven in the direction of the arrow in the figure, and accordingly, the rolling roller 17 is also rotated in the direction of the arrow. In this state, a material such as plastic or biomass that has been crushed to an appropriate size according to the size of the die hole diameter is charged into the die ring 16 from a charging port (not shown). The roller 17 is pressed into the die hole 160 of the die ring 16 while being crushed and compressed between the inner peripheral surface of the die ring (there is also a crushing action by crushing). The material pushed into the die hole 160 is compressed in the process of passing through the die hole 160, and the surface of the plastic (surface in contact with the inner peripheral surface of the die hole) is compressed by frictional heat with the inner peripheral surface of the die hole. Biomass or the like is at least partially melted or softened. The material that has passed through the die hole 160 is sequentially extruded in a cylindrical shape to the outer peripheral surface side of the die ring 16, and at this time, the plastic or biomass on the surface that has been melted or softened is solidified. An outer shell is formed using solidified plastic or biomass as a binder. Then, when the cylindrical molded product pushed out to the outer peripheral surface of the die ring reaches the position of the cutting blade 18 by the rotation of the die ring 16, it is scraped off from the outer peripheral surface of the die ring 16 by the cutting blade 18, thereby A molded product (organic substance formed into granules) is obtained.

In the present invention, a liquid product (hereinafter referred to as “liquid product (p _L )”) generated by a low molecular weight reaction by reforming an organic substance is combusted in a combustion furnace, and the molecular weight is reduced by the combustion heat. It is preferable to supply the reaction heat of the low molecular weight to the reactor, that is, use the heat of combustion of the liquid product (p _L ) generated in the low molecular weight system as a heat source for the low molecular weight reaction. The liquid product (p _L ) has an average molecular weight of about 370 and has a combustion heat of about 37 MJ / L, which is the same physical property as light oil, and is therefore suitable for being used as a heat source after being burned.

There is no particular restriction on the form of supplying the low molecular weight reaction heat to the low molecular weight reactor with the combustion heat of the liquid product (p _L ), but examples include the following forms (i) and (ii): It is done.
(I) the liquid product by indirect heat the inside of the low molecular weight reactor the combustion gases (p _L), the liquid product (p _L) low molecular weight reaction heat to the low molecular weight reactor the combustion heat of Supply.
(Ii) A fluidized bed reactor is used as the low molecular weight reactor, a part of the fluidized medium is extracted from the fluidized bed reactor, and this fluidized medium is introduced into a combustion furnace for the liquid product (p _L ). Heating with the combustion heat of the liquid product (p _L ), and circulating the heated fluidized medium to the fluidized bed reactor, the temperature of the liquid product (p _L ) is reduced to the low molecular weight reactor with the combustion heat. Supply heat of molecularization reaction.

In the form (i), for example, (1) the liquid product (p _L ) is combusted in a combustion furnace, and the combustion gas (hot air) is caused to flow through a heat transfer tube installed in the low molecular weight reactor. , Indirect heating of the interior of the low molecular weight reactor, (2) Indirect heating of the reactor from the outside with combustion gas (hot air), as used in steam reforming furnaces, ie, combustion furnace A low molecular weight reactor is placed inside, and the low molecular weight reactor is indirectly heated from the outside with the combustion gas (hot air) of the liquid product (p _L ) generated in the combustion furnace. (3) Low molecular weight The external heating rotary kiln can be used as a gasification reactor, the liquid product (p _L ) is burned in a combustion furnace, and the combustion gas (hot air) is supplied to the external heating rotary kiln as a heat source. it can.

The form (ii) is particularly preferable because the heat of combustion of the liquid product (p _L ) is directly supplied to the inside of the depolymerization reactor through the fluid medium, and thus the heat transfer efficiency is high. As a combustion furnace used in this form, a rotary kiln combustion furnace or a fluidized bed combustion furnace is preferable.
When a rotary kiln combustion furnace is used, the liquid medium (p _L ) is combusted in the rotary kiln combustion furnace while the fluid medium extracted from the fluidized bed reactor (low molecular weight reactor) is sequentially rotary kiln burned. It is introduced into the furnace and heated with combustion heat, and the fluidized medium heated and discharged sequentially from the rotary kiln combustion furnace is returned to the fluidized bed reactor (low molecular weight reactor). When using a fluidized bed combustion furnace, the fluidized medium extracted from the fluidized bed reactor (low molecular weight reactor) is sequentially introduced into the fluidized bed combustion furnace to form a fluidized bed, The liquid product (p _L ) is combusted in the fluidized bed combustion furnace, the fluidized medium is heated with the combustion heat, and the fluidized medium sequentially heated and discharged from the fluidized bed combustion furnace is fluidized bed reactor (low molecular weight reactor). To the reactor. That is, in any case, the fluidized medium is withdrawn from the fluidized bed reactor (low molecular weight reactor) by a certain amount and circulated between the fluidized bed reactor and the combustion furnace.
Note that the fluidized bed combustion furnace may be formed not only with a normal bubble fluidized bed but also with a high-speed fluidized bed.

As a fluidized medium when using a fluidized bed reactor as a low molecular weight reactor, there is no particular limitation as long as it is a substance that can withstand heating in a combustion furnace and is suitable for a fluidized bed. It is preferable because powder particles such as silicon oxide, aluminum oxide, magnesium oxide, iron oxide and nickel oxide are industrially available at low cost, and one or more of these can be used. In addition, when iron oxide or nickel oxide is used as a fluid medium, in addition to acting as a mere fluid medium, it also acts as a catalyst for the molecular weight reduction reaction, so the fluidized bed reactor can be downsized or the molecular weight can be reduced. An effect of reducing the reaction temperature can be obtained.
Since the fluidized medium is difficult to form a stable fluidized bed if the average particle size is too small or too large, the average particle size is preferably about 30 to 300 μm, more preferably about 50 to 200 μm.

FIG. 5 shows another embodiment of the facility for reducing the molecular weight of an organic substance used in the practice of the present invention, in which the combustion heat of the liquid product (p _L ) generated in the molecular weight reduction system is reduced. An embodiment is shown that is utilized as a heat source for the reaction.
In FIG, 6 is a combustion furnace for combusting a liquid product produced in a low molecular reactions of organic substances with low molecular weight reactor 2 (p _L), the liquid product in the combustion furnace 6 (p _L The low molecular weight reaction heat 2 is supplied to the low molecular weight reactor 2 by the combustion heat generated by the combustion of (2). This embodiment includes an indirect heating mechanism that indirectly heats the interior of the low molecular weight reactor 2 with the combustion gas of the liquid product (p _L ). Specifically, the low molecular weight reduction reaction is provided in the combustion furnace 6. The low molecular weight reactor 2 is indirectly heated from the outside by the combustion gas (hot air) of the liquid product (p _L ) generated in the combustion furnace 6.

Further, 19 is a combustion burner of the combustion furnace 6, 20 is a temporary storage tank for the liquid product (p _L ) separated by the separator 9, and 21 is liquid generation from the temporary storage tank 20 to the combustion furnace 6 (combustion burner 19). A liquid feed pipe for feeding the product (p _L ), 22 is a supply pump for the liquid product (p _L ) provided in the liquid feed pipe 21, and 23 is a combustion support for the combustion burner 19 of the combustion furnace 6 such as combustion air. A supply pipe 24 for supplying gas (hereinafter, “combustion air” will be described as an example), and 24 is a combustion air flow control valve provided in the supply pipe 23.
As described above, the low molecular weight reactor 2 can be composed of, for example, a moving bed reactor such as an external heating rotary kiln, a fluidized bed reactor, a fixed bed reactor, or the like. However, in the present embodiment, the low molecular weight reactor 2 is arranged in the combustion furnace 6, and the low molecular weight reactor 2 is generated by the combustion gas (hot air) of the liquid product (p _L ) generated in the combustion furnace 6. In general, the low molecular weight reactor 2 is constituted by a fixed bed reactor.

There is no particular limitation on the form of the combustion burner 19 wherein combustion furnace 6 comprises, since the physical properties of the liquid product (p _L) is about light oil, light oil burner is preferably inexpensive. In consideration of the increase in the viscosity of the liquid product (p _L ) in the severe cold season, the liquid feeding tube 21 may be heated with a steam trace or the like. Although the steam used for this is not specifically limited, the low pressure steam of the pressure of about several kg / cm < ² > may be sufficient.
Other configurations in FIG. 5 are the same as those in FIG. 1, and thus the same reference numerals are given and detailed descriptions thereof are omitted.

In the operation of the facility shown in FIG. 5, an organic substance is introduced into the low molecular weight reactor 2 by blowing with a carrier gas or dropping from a quantitative charging device in the raw material charging mechanism 4. On the other hand, a part of the mixed gas (g) is supplied through the gas supply pipe 5 and used as the carrier gas or the sealing gas of the metering charge device, as in the embodiment of FIGS. is there.
The reformed product (low molecular weight product) taken out from the low molecular weight reactor 2 is washed with water in the gas scrubber 8 so that the liquid product (p _L ) is condensed and separated from the gas product. The mixture of the liquid product (p _L ) and water is sent to the separator 9 to separate the water, and the entire amount of the liquid product (p _L ) is sent to the temporary storage tank 20 through the supply pipe 25 and stored. The The liquid product (p _L ) in the temporary storage tank 20 is sent to the combustion burner 19 of the combustion furnace 6 by the liquid feeding pipe 21 and the supply pump 22. Combustion air is supplied to the combustion burner 19 by a supply pipe 23 and a flow rate control valve 24, and the liquid product (p _L ) is combusted by the combustion air, and the low molecular weight reactor 2 is burned by the combustion gas. Indirect heating from outside.

FIG. 6 schematically shows another embodiment of the facility for reducing the molecular weight of an organic substance used in the practice of the present invention, which is also a liquid product (p _L ) generated in the molecular weight reduction system. In this embodiment, the low molecular weight reactor 2 is composed of a fluidized bed reactor 2a, and the combustion furnace 6 is composed of a rotary kiln combustion furnace 6a. ing.
In this embodiment, there is provided a fluid medium circulation mechanism 7 that extracts a part of the fluid medium of the fluidized bed reactor 2a and circulates it with the rotary kiln combustion furnace 6a. The fluidized-medium circulation mechanism 7 extracts the fluidized medium from the fluidized bed reactor 2a and introduces it into the rotary kiln combustion furnace 6a, and the fluidized medium heated in the rotary kiln combustion furnace 6a as the fluidized bed reactor 2a. It is comprised with the return pipe | tube 27 which returns.
The other configurations in FIG. 6 are the same as those in FIG. 1 and FIG.

A fixed amount of the fluidized medium is withdrawn from the fluidized bed reactor 2a through the extraction pipe 26, and this fluidized medium is introduced into the rotary kiln combustion furnace 6a and heated with the combustion heat of the liquid product (p _L ). By returning (circulating) the fluidized medium to the fluidized bed reactor 2a through the return pipe 27, the low molecular weight reactor 2 (fluidized bed reactor 2a) is reduced in molecular weight by the heat of combustion of the liquid product (p _L ). To supply heat of reaction.
The fluid medium extracted from the fluidized bed reactor 2a through the extraction pipe 26 is introduced into the furnace from one end side of the rotary kiln combustion furnace 6a. On the other hand, the liquid product (p _L ) is supplied from the temporary storage tank 20 to the combustion burner (not shown) of the rotary kiln combustion furnace 6a by the liquid supply pipe 21 and the supply pump 22, and the supply pipe 23 and the flow rate are adjusted. Combustion air is supplied by the valve 24, the liquid product (p _L ) is combusted by the combustion air, and the fluid medium is heated by the combustion heat (high-temperature combustion gas). The fluidized medium thus heated is discharged from the other end of the rotary kiln combustion furnace 6a and returned to the fluidized bed reactor 2a through the return pipe 27.

In this embodiment, the low molecular weight reactor 2 (fluidized bed reactor 2a) can be directly supplied with the low molecular weight reactor 2 by the fluidized medium heated in the rotary kiln combustion furnace 6a, and the heat transfer efficiency is high. It is a feature.
Also in this embodiment, an organic substance is charged into the low molecular weight reactor 2 (fluidized bed reactor 2a) by blowing with carrier gas or dropping from a quantitative charging device in the raw material charging mechanism 4, A part of the mixed gas (g) is supplied to the raw material charging mechanism 4 through the gas supply pipe 5 and used as the carrier gas or the sealing gas of the quantitative charging device. This is the same as the embodiment.
In this embodiment, the flow direction of the combustion gas of the liquid product (p _L ) in the rotary kiln combustion furnace 6a and the moving direction of the fluidized medium are countercurrent (opposite directions), but the liquid product (p _L The flow direction of the combustion gas and the moving direction of the fluidized medium may be combined (in the same direction).

Moreover, although the combustion furnace 6 of embodiment of FIG. 6 is comprised by the rotary kiln combustion furnace 6a, you may comprise by a fluidized-bed combustion furnace (a high-speed fluidized-bed combustion furnace etc. are included), for example.
In addition, as in the embodiment of FIG. 6, the low molecular weight reactor is configured by a fluidized bed type reactor 2a, and a fluidized bed type reaction is performed with an organic substance using a part of the mixed gas (g) as a carrier gas. When blowing into the reactor 2a, the lower layer (preferably the lower end) of the fluidized bed of the fluidized bed reactor 2a is preferably used as the blowing position of the organic substance using the mixed gas (g) as the carrier gas. This is because the mixed gas (g), which is a carrier gas, is more likely to contribute to the lowering reaction of the organic substance by blowing into the lower region (preferably the lower end) of the fluidized bed, and the lowering efficiency of the organic substance is increased. This is advantageous.

FIG. 7 shows an embodiment of that case. In the figure, 28 is a dispersion plate of the fluidized bed reactor 2a, and the space below the dispersion plate 28 forms a wind box portion 29, to which the gas supply pipe 3 is connected. . A fluidized medium is inserted into the space above the dispersion plate 28, and a fluidized bed 30 is formed by the mixed gas (g) blown out from the dispersion plate 28.
The blowing pipe 15 constituting the raw material charging mechanism 4 is connected to a position in the vicinity of the lower end of the fluidized bed 30 (a position immediately above the dispersion plate 28), and an organic substance is blown obliquely upward from the blowing pipe 15 by the carrier gas. Yes.
In addition, the other structure of the raw material injection | throwing-in mechanism 4 is the same as that of embodiment of FIG.

Using equipment having the apparatus configuration as shown in FIG. 6, an organic substance is reformed in the externally heated fluidized bed reactor 2a (lower molecular weight reactor) to lower the molecular weight, and a mixed gas (g) An operation test was conducted in which a part of was used as a carrier gas for organic materials.
In this test apparatus, the organic substance was blown from the lower part of the fluidized bed reactor 2a as shown in FIG.

The average composition of the carbon monoxide-containing gas (g ₀ ) supplied from outside the system (outside of the process) is H ₂ : 4 vol%, CO: 23 vol%, CO ₂ : 23 vol%, H ₂ O: 0 vol%, N ₂ : It was 50 vol%. A carbon monoxide-containing gas (g ₀ ) is supplied to a steam mixer (not shown) at 74 Nm ³ / h and steam at a pressure of 10 kg / cm ² G is supplied as 67 Nm ³ / h, and this mixed gas is subjected to a shift reaction. Introduced into the vessel 1 to perform a shift reaction, a mixed gas having a gas composition of H ₂ : 14 vol%, CO: 0 vol%, CO ₂ : 24 vol%, H ₂ O: 35 vol%, N ₂ : 27 vol% (g) (Shift reaction product gas) was obtained. The mixed gas (g) had a flow rate of 141 Nm ³ / h (mass flow rate of 155 kg / h) and a shift reactor outlet gas temperature of 306 ° C. The mixed gas (g) is supplied to the fluidized bed reactor 2a (low molecular weight reactor) through the gas supply pipe 3, and the mixed gas (g) is supplied through the gas supply pipe 5 branched from the gas supply pipe 3. 80 Nm ³ / h (mass flow rate of 88 kg / h) was supplied to the raw material charging mechanism 4 and used as a carrier gas for organic substances. Accordingly, the mixed gas directly supplied to the fluidized bed reactor 2a through the gas supply pipe 3 is 61 Nm ³ / h, but the mixed gas (g) blown as the carrier gas from the lower part of the fluidized bed reactor 2a also flows. Since it reacts with the organic substance in the layer, the total amount of the mixed gas (g) which reacts with the organic substance is 141 Nm ³ / h.

The externally heated fluidized bed reactor 2a is preheated to 500 ° C., and this fluidized bed reactor introduces the above mixed gas (g) (shift reaction product gas) into 2a. As a model material of waste plastic, polyethylene molded into a cylindrical shape having an outer diameter of 3 mm and a length of 6 to 12 mm in a ring die type compression molding granulator is supplied at 880 kg / h (the solid-gas ratio to the carrier gas is 10 kg / kg), and the temperature was raised to 600 ° C., which is the planned reaction temperature. After reaching 600 ° C., the low molecular weight reaction of the waste plastic was continued for 1 hour. During this time, the fluidized medium (converter-generated dust having an average particle size of 80 μm) of the fluidized bed reactor 2a is withdrawn by a certain amount through the extraction pipe 26 and supplied to the rotary kiln combustion furnace 6a and stored in the temporary storage tank 20. The liquid product (p _L ) was supplied to the combustion burner of the rotary kiln combustion furnace 6a through the liquid feeding pipe 21 and burned at an air ratio of 1.2, and the fluidized medium was heated with the combustion heat (combustion gas). The fluid medium heated in the rotary kiln combustion furnace 6a was returned to the fluidized bed reactor 2a through the return pipe 27, and used as a heat source for the low molecular weight reaction.

Since the heat of combustion of the liquid product (p _L ) was used as a heat source for the low molecular weight reaction, the low molecular weight reaction temperature could be stably controlled at 600 ± 10 ° C. In addition, there are no supply problems such as shelves and blockages of polyethylene, which is a model material of waste plastic, during operation, and there is no gas leakage from the organic material supply line, allowing stable operation. It was. As a gas product, a gas having a lower combustion heat of 6.5 Mcal / Nm ^{3 on} average of three analysis values was obtained in a yield of 68 mol%.

For comparison, nitrogen was used as a carrier gas for polyethylene, the flow rate was 40 Nm ³ / h (50 kg / h), the solid-gas ratio was 17.6 kg / kg, and the mixed gas (141 Nm ³ / h) A test (comparative example) was conducted in the same manner as in the above invention example except that the whole amount was supplied to the fluidized bed reactor 2a.
Since polyethylene was molded into a cylindrical shape and nitrogen was used as the carrier gas, there was no supply trouble such as hanging and blocking polyethylene, but the lower combustion heat of the gas product was 4.7 Mcal / Nm. ^{3. The} gas yield was 46 moL%, which was significantly lower than that of the above invention examples.

DESCRIPTION OF SYMBOLS 1 Shift reactor 2 Low molecular weight reactor 2a Fluidized bed type reactor 3 Gas supply pipe 4 Raw material input mechanism 5 Gas supply pipe 6 Combustion furnace 6a Rotary kiln combustion furnace 7 Fluidized medium circulation mechanism 8 Gas scrubber 9 Separator 10 Quantitative equipment Inserting device 11 Raw material hopper 12 Charging pipe 13 Constant supply device 14 Raw material hopper 15 Blowing pipe 16 Die ring 17 Rolling roller 18 Cutting blade 19 Combustion burner 20 Temporary storage tank 21 Liquid feed pipe 22 Supply pump 23 Supply pipe 24 Flow rate control valve 25 Supply pipe 26 Extraction pipe 27 Return pipe 28 Dispersion plate 29 Air box part 30 Fluidized bed 100 Raw material transfer part 160 Die hole

Claims (13)

A mixture containing hydrogen and carbon dioxide generated by the shift reaction and water vapor not consumed in the shift reaction by adding excess water vapor to the gas (g ₀ ) containing carbon monoxide to cause the shift reaction. A gas (g) is a method of bringing a mixed gas (g) into contact with an organic substance in a molecular weight reduction reactor and modifying the organic substance to reduce the molecular weight.
The organic material molded into granules, when introduced into the low molecular weight reactor by dropping charged from quantitative charging apparatus, using a portion of the mixed gas (g) as a seal gas of the quantitative charging apparatus A method for reducing the molecular weight of an organic substance. 2. The method for reducing the molecular weight of an organic substance according to claim 1, wherein the gas (g ₀ ) containing carbon monoxide has a carbon monoxide concentration of 5 vol% or more and a nitrogen concentration of 60 vol% or less. The method for reducing the molecular weight of an organic substance according to claim 2, wherein the gas (g ₀ ) containing carbon monoxide has a carbon monoxide concentration of 10 vol% or more and a nitrogen concentration of 55 vol% or less. The liquid product (p _L ) generated by the molecular weight reduction reaction by reforming the organic substance is combusted in a combustion furnace, and the heat of combustion supplies the low molecular weight reaction reactor to the molecular weight reduction reactor. The method for reducing the molecular weight of an organic substance according to claim 1. By indirectly heating the inside of the low molecular weight reactor the combustion gases of a liquid product (p _L), and supplies the low molecular weight reaction heat by heat of combustion of the liquid product (p _L) in the low molecular weight reactor The method for reducing the molecular weight of an organic substance according to claim 4. The low molecular weight reactor is a fluidized bed reactor,
Extracting a part of the fluidized medium from the flowable layer reactor, heating the fluidized medium in the heat of combustion of the liquid product (p _L) Liquid product is introduced into the combustion furnace (p _L), the heating The low molecularization reaction heat is supplied to the low molecular weight reactor by the combustion heat of the liquid product (p _L ) by circulating the fluidized medium in the fluidized bed reactor. For reducing the molecular weight of organic substances. The method for reducing the molecular weight of an organic substance according to claim 6, wherein the combustion furnace for the liquid product (p _L ) is a rotary kiln combustion furnace or a fluidized bed combustion furnace.   The method for reducing the molecular weight of an organic substance according to claim 6 or 7, wherein the fluid medium is at least one selected from silicon oxide, aluminum oxide, magnesium oxide, iron oxide, and nickel oxide. A mixture containing hydrogen and carbon dioxide generated by the shift reaction and water vapor not consumed in the shift reaction by adding excess water vapor to the gas (g ₀ ) containing carbon monoxide to cause the shift reaction. A shift reactor (1) to obtain gas (g);
A low molecular weight reactor (2) for bringing the mixed gas (g) obtained in the shift reactor (1) into contact with an organic substance and modifying the organic substance to reduce the molecular weight;
A gas supply pipe (3) for supplying the mixed gas (g) obtained in the shift reactor (1) to the low molecular weight reactor (2);
A raw material charging mechanism (4) for charging the organic material formed into a granular form into the low molecular weight reactor (2) by dropping from the quantitative charging device,
A gas supply pipe (5) is provided that branches from the gas supply pipe (3) and supplies a part of the mixed gas (g) to the raw material charging mechanism (4) as a seal gas of the quantitative charging device. Equipment for reducing the molecular weight of organic substances. Furthermore, a combustion furnace (6) for burning the liquid product (p _L ) generated by the molecular weight reduction reaction by reforming the organic substance in the molecular weight reduction reactor (2) is provided, and the combustion furnace (6) The low molecular weight reaction heat is supplied to the low molecular weight reactor (2) by the combustion heat generated by the combustion of the liquid product (p _L ). Molecularization equipment. The equipment for reducing the molecular weight of an organic substance according to claim 10, further comprising an indirect heating mechanism for indirectly heating the inside of the molecular weight-reducing reactor (2) with the combustion gas of the liquid product (p _L ). The low molecular weight reactor (2) consists of a fluidized bed reactor (2a),
A part of the fluidized medium is withdrawn from the fluidized bed reactor (2a), and this fluidized medium is introduced into the combustion furnace (6) of the liquid product (p _L ), and the liquid product ( low molecular weight organic material according to claim 10, characterized in that it comprises p _L) of the heated fluidized medium a fluidized bed reactor with combustion heat of the (fluidized medium circulating mechanism that circulates in 2a) (7) Facility. The apparatus for reducing the molecular weight of organic substances according to claim 12, wherein the combustion furnace (6) for the liquid product (p _L ) is a rotary kiln combustion furnace or a fluidized bed combustion furnace.

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