JP7202749B1 - Fuel gas generator and method - Google Patents

Abstract

A fuel gas generator and a fuel gas generation method are provided. The present invention provides a fuel gas generator, which includes a split tower furnace and a heating facility, the split tower furnace including a containment space, a first gas induction unit and at least one gas generator. It is divided into a lower mixing chamber, a middle mixing chamber and an upper mixing chamber by three second gas induction units, and the at least one second gas induction unit has a plurality of cyclonic blowing units. The present invention further provides a method for generating fuel gas. The fuel gas generation apparatus and method of the present invention has excellent heat conduction and mass transfer effects, and can also perform a pyrolysis reaction to produce reusable fuel gas and reduce overall energy consumption. In addition, it is possible to realize the concept of a circular economy. [Selection figure] None

Description

TECHNICAL FIELD The present invention relates to a fuel gas generating apparatus and method, and more particularly to a fuel gas generating apparatus and method using waste.

Common waste disposal methods include incineration, pyrolysis, melting and smelting. All of these operate thermochemical processes to change the composition and physical, chemical and biological properties of the waste.

The treatment temperature of the above incineration, melting and smelting methods should all reach 1000°C, among which the incineration method decomposes organic matter into stable gases such as harmless carbon dioxide and water vapor. , and into matter. The melting process oxidizes harmful organics or volatilizes heavy metals, leaving the remaining harmful substances in the slag. Smelting also introduces waste into the metal hot smelting process. Incineration, melting and smelting all require the input of large amounts of fuel or energy sources, resulting in high processing costs.

The treatment temperature of pyrolysis is relatively low, generally lower than 1000°C, and the resulting product can contain fuel or chemical feedstock, for example, Chinese Patent Publication No. CN109628682B describes waste plastic It is decomposed into gas and used in steelmaking. However, how to effectively improve the conversion efficiency of waste to fuel or chemical feedstock is a question that needs continued research.

To solve the above problems, the present invention provides a fuel gas generator, which includes:
including a split tower furnace, which
accommodation space,
a first gas induction unit having a plurality of spaced perforations and at least one second gas induction unit having a plurality of through holes and a plurality of cyclonic blowing units;
wherein the plurality of through holes are spaced apart from each other, each of the cyclone blowing units has a communicating passage, and the communicating passage of each of the cyclone blowing units is aligned with each of the through holes. said first gas induction unit and said at least one second gas induction unit are arranged in order from the bottom to the top of said split tower furnace in correspondence and communication with each other, whereby The containment space is partitioned into a plurality of layers of mixing chambers in communication with each other, wherein the layers of mixing chamber are located between the bottom of the split tower furnace and the first gas induction unit. a middle mixing chamber located between said first gas induction unit and said at least one second gas induction unit; and a top of said split tower furnace and said at least one second gas induction unit. including an upper mixing chamber located between the units,
an air inlet used to provide reactant gases;
a first material supply port used to provide a thermally conductive material;
a second material supply port used to provide organic matter;
a first outlet used for discharging the target organic matter after treatment, and the target organic matter after treatment contains the fuel gas; and
including a second outlet for discharging the thermally conductive material;
Among them, the accommodation space, the air supply port, the first material supply port, the second material supply port, the first discharge port, and the second discharge port communicate with each other, and the air supply port is installed in the lower mixing chamber, and
A heating facility connected to or surrounding the split tower furnace.

The air inlet and the first gas induction unit installed in the present invention allow the heat conducting material, the target organic matter and the reaction gas to form a fluidized bed in the containing space, thereby improving the efficiency of heat conduction and mass transfer. and greatly improve the mixing effect of the heat-conducting material, the target organic matter and the reaction gas by means of the plurality of cyclonic blowing units of the at least one second gas induction unit. This enhances the effectiveness of pyrolysis, reduces or prevents dioxin formation, and reduces or prevents scale formation inside the split-layer furnace. In addition, compared with the conventional single furnace tube, the present invention partitions into a plurality of layers of mixing chambers by means of a first gas induction unit and at least one second gas induction unit, and each layer of mixing chamber Since the reaction environment of the pyrolysis method can be precisely and accurately controlled, the effect of pyrolysis can be further improved, and the fuel gas content in the upper mixing chamber can be increased.

The present invention is based on converting the target organic matter into fuel gas by thermochemical treatment, and since the target organic matter belongs to waste, the present invention can achieve the purpose of reducing the volume and weight of waste, and can also be reused. It belongs to the new green chemistry category as it is capable of generating renewable fuel gas and turning waste into a resource.

In an embodiment, the split tower furnace has a tubular shape.

In an embodiment, the split tower furnace has an inner wall, and the inner wall surrounds the containment space.

In the example, the first material supply port is installed in the upper mixing chamber, but it is not limited to this. Preferably, the first material feed port is located at the top of the split tower furnace and can also serve as a sight hole at the same time.

In the example, the second material supply port is installed in the middle layer mixing chamber, but it is not limited to this.

In the embodiment, the first discharge port is installed in the upper mixing chamber, but is not limited to this. Preferably, said first outlet is adjacent to the top of said split tower furnace.

In the embodiment, the second discharge port is installed in the lower mixing chamber, but is not limited to this. Preferably, the second outlet is located at the bottom of the split-layer furnace to facilitate collection of heat transfer material or non-gasified target organics.

In an embodiment, the width of the upper mixing chamber tapers in the direction from the at least one second gas induction unit toward the top of the split tower furnace. In other words, the width of the portion adjacent to the top of the split tower furnace is greater than the width of the portion adjacent to the at least one second gas induction unit. The present invention effectively reduces the rising speed of the target organic matter through the design of gradually widening the width of the upper mixing chamber, and also prevents the heat-conducting material from overflowing from the first material supply port, or even completely Solid granules of non-gasified target organic matter can be prevented from entering the first outlet.

In embodiments, the width of the upper mixing chamber is greater than the width of the middle mixing chamber.

In an embodiment, a filter is installed in the upper mixing chamber. Preferably, said filter is placed between said first outlet and said at least one second gas induction unit. More preferably, the filter is installed at a location where the width of the upper mixing chamber begins to gradually widen, thereby preventing solid granules of the target organic matter that have not yet been completely gasified from entering the first outlet. Strengthen prevention.

In an embodiment, the at least one second gas induction unit comprises one second gas induction unit.

In an embodiment, the at least one second gas induction unit comprises a plurality of second gas induction units, and any one mixing chamber located between any two of the adjacent second gas induction units is This is the middle and upper mixing chamber. Preferably, said plurality of second gas directing units are parallel to each other. More preferably, said plurality of second gas induction units is between two and eight.

In an embodiment, the plurality of second gas induction units are connected in parallel with each other. Preferably, the plurality of second gas induction units are connected in parallel in order along the direction from the bottom to the top of the split tower furnace, for example, the plurality of second gas induction units are connected to two second gas induction units, which are installed in order along the direction from the bottom to the top of the split tower furnace, and are each connected to at least one gas induction equipment, so that the at least one gas induction equipment is It is advantageous to supply gas to each said second gas induction unit at the same time. In other words, after the reactant gas is first sent to the second gas induction unit adjacent to the bottom of the split tower furnace, the surplus Rather than being sent to a gas induction unit, the reaction gas is diverted to each of the second gas induction units immediately after leaving the at least one gas induction arrangement.

In an embodiment, the width of the upper mixing chamber is greater than the width of each of the middle and upper mixing chambers.

In an embodiment, the widths of the lower mixing chamber, the middle mixing chamber and each of the middle and upper mixing chambers are all the same.

In an embodiment, said first gas directing unit has opposed first and second planes, and each said perforation extends from said first plane to said second plane, and the sum of said first planes. Based on the area, the total cross-sectional area of each of the perforations located on the first plane is 0.1-1.5%.

According to the invention, the first plane of said first gas induction unit faces the top of said split tower furnace and the total area of said first plane does not deduct the cross-sectional area of each said perforation. .

In an embodiment, the first gas directing unit is a reactive gas distribution plate. Preferably, the material of the reaction gas distribution plate is stainless steel, but the material is not limited to this.

In an embodiment, the first gas induction unit is installed horizontally, ie approximately perpendicular to the bottom-to-top direction of the split tower furnace.

In an embodiment, the first gas induction unit is connected to the inner wall of the split tower furnace, thereby partitioning it into a plurality of mixing chambers. Preferably, said first gas induction unit is in direct contact with the inner wall of said split tower furnace.

In an embodiment, each said second gas induction unit is installed horizontally, ie approximately perpendicular to the bottom-to-top direction of said split tower furnace. Preferably, said first gas induction unit and each said second gas induction unit are parallel.

In an embodiment, each of said second gas induction units is connected to the inner wall of said split tower furnace, thereby partitioning it into a plurality of mixing chambers. Preferably, each said second gas induction unit is in direct contact with the inner wall of said split tower furnace.

In an embodiment, the communication passage of each cyclonic blowing unit has a tubular shape. Preferably, the diameter or longest inner diameter of the communication path is greater than the height of the communication path. More preferably, half of the radius or longest inner diameter of the communication path is greater than the height of the communication path.

In an embodiment, the communicating passage of each cyclonic blowing unit and each through-hole are exactly one-to-one and tightly fitted to each other. Preferably, the diameter or the longest inner diameter of the communication passage of each cyclone blowing unit and the diameter or the longest inner diameter of each of the through holes are equal.

In an embodiment, each said cyclonic fumarolic unit has a plurality of fumaroles, wherein each said fumarole has a fumarole and an air inlet communicating with each other, and the fumarole of each said fumarine is: They face the communication passage of the cyclone type fumarolic unit to which they belong. Preferably, the fumaroles of each said fumarole are all oriented in a clockwise or counterclockwise direction, thereby providing a cyclonic airflow.

In an embodiment, the fumaroles of each of the fumarole pipes are spaced apart from each other in the communication passage of the associated cyclonic fumarolic unit, so as to form a cyclonic airflow in the communication passage of the associated cyclonic fumarolic unit. be advantageous to

In some embodiments, each of the fumaroles has a straight shape or an arcuate shape. Preferably, each said fumarole has an arcuate shape, which further enhances the swirling degree of the cyclonic airflow.

In an embodiment, each said fumarole is installed substantially tangentially to the outer edge of the communication passage of the associated cyclonic fumarole unit, thereby further enhancing the degree of swirl of the cyclonic airflow.

In an embodiment, the blowing direction of the blowing port of each said blowing pipe is substantially parallel to the tangential direction of the outer edge of the communication passage of the associated cyclonic blowing unit, thereby further enhancing the degree of swirl of the cyclonic blowing air.

In an embodiment, the cross-sectional outline of each said cyclonic fumarolic unit exhibits a substantially polygonal shape, for example a pentagon, hexagon, heptagon, octagon or nine-sided shape, and each said cyclone The cross-sectional direction of the fumarolic unit is substantially perpendicular to the bottom-to-top direction of the split tower furnace. Preferably, a fumarole is provided on each side of the polygon. More preferably, each said fumarole pipe protrudes away from the communication passage of the cyclone fumarole unit to which it belongs. In other words, the inlet of each said fumarole is located outside said polygon, which is advantageous for coupling with said at least one gas induction facility.

In an embodiment, the cross-sectional outline of each said cyclonic fuming unit is substantially circular, and the cross-sectional direction of each said cyclonic fuming unit is substantially perpendicular to the bottom-to-top direction of said split tower furnace. is. Preferably, each said fumarole pipe projects away from the communication passage of the associated cyclonic fumarole unit. In other words, the inlet of each said fumarole is located outside said circle, which is advantageous for coupling with said at least one gas induction facility.

In an embodiment, the direction of air flow in each of the perforations of the first gas induction unit and each of the through holes of the at least one second gas induction unit are all from the bottom to the top of the split tower furnace. , thereby forming an ascending gas phase. By comparison, each of the cyclonic blowing units blows in a direction perpendicular to the bottom-to-top direction of the split tower furnace. In other words, each cyclonic blowing unit blows horizontally.

In embodiments, the heating equipment is connected to or surrounds any one or combination of the lower mixing chamber, the middle mixing chamber, the middle upper mixing chamber and the upper mixing chamber. Preferably, the heating equipment is connected to or surrounds the middle and upper mixing chamber and/or the upper mixing chamber. More preferably, the heating facility is connected to or surrounds a portion of the upper mixing chamber adjacent to the at least one second gas induction unit.

In an embodiment, the fuel gas generator of the present invention further includes transportation equipment, which is connected to the second material supply port. Preferably, the transportation equipment includes a screw conveyor or an air conveyor.

In an embodiment, the fuel gas generator of the present invention further comprises at least one gas induction facility connected to the air inlet, preferably the at least one gas induction facility is a Roots blower, a centrifugal blower, a ring Includes type blower or axial blower.

In an embodiment, said at least one gas induction facility is connected to said air supply and to the inlet of each said fumarole. Preferably, said at least one gas induction facility is connected to the inlet of each said fumarolic pipe by at least one long pipe.

In an embodiment, the at least one gas induction facility is a gas induction facility, and the gas induction facility is respectively connected to the air supply port and the intake port of each of the fumarole pipes.

In an embodiment, the at least one gas induction facility is a plurality of gas induction facilities, and the plurality of gas induction facilities comprises a first gas induction facility coupled with the air supply port, and each of the fumarolic pipes. including a second gas induction facility connected to the inlet of the

In an embodiment, the at least one gas induction facility is equipped with an orifice flow meter and/or a warmer.

In an embodiment, the fuel gas generator of the present invention further comprises a heat exchange device, in communication with the first outlet. The heat exchange equipment installed in the present invention is capable of recovering thermal energy in the fuel gas and transporting it to the heating equipment of the fuel gas generator and/or the heater of the at least one gas induction equipment. Yes, which reduces overall energy consumption and waste heat.

In embodiments, the heating equipment of the present invention includes electric heaters, boiler heaters or radio frequency heaters. Preferably, the heating temperature of the heating equipment is 400° C. or higher and 950° C. or lower, for example, 400° C., 500° C., 600° C., 700° C., 800° C., 900° C. or 950° C., but not limited thereto. .

In addition, the present invention provides a fuel gas generation method, which comprises:
providing the thermally conductive material, the target organic matter and the reaction gas to the fuel gas generator, and fluidizing the thermally conductive material, the target organic matter and the reaction gas to form a fluidized bed in the containment space; ,as well as,
A gasification step of heating the fluidized bed to gasify the target organic matter to obtain the fuel gas.

According to the present invention, "gasifying the target organic matter" refers to converting the target organic matter into a fuel gas by pyrolysis.

In an embodiment, the fluidizing step includes:
A filling step of filling the accommodation space with the thermally conductive material from the first material supply port;
a preheating step of increasing the temperature of the housing space with the heating equipment;
A material input step of inputting the target organic matter from the second material supply port; and
The reaction gas is introduced from the air supply port, and the reaction gas is fed through the perforations of the first gas induction unit, the through holes of the at least one second gas induction unit, and the cyclone blowing units. A gas guiding step of forming an ascending gas phase by sequentially passing through passages and causing the reaction gas to reach the upper mixing chamber after passing from the lower mixing chamber to the middle mixing chamber,
and providing a cyclonic airflow by admitting the reaction gas from each of the cyclonic blowing units of the at least one second gas induction unit.

In embodiments, the heating temperature during the gasification step is from 400° C. to 950° C., such as 400° C., 500° C., 600° C., 700° C., 800° C., 900° C. or 950° C., but these is not limited to

In an embodiment, the preheating step and the gasifying step employ the same temperature.

In an embodiment, the fuel gas generation method of the present invention further comprises a fuel gas heat recovery step, wherein a heat exchange facility is connected to the first outlet of the split-layer furnace to convert the thermal energy of the fuel gas to While recovering, the thermal energy is transported to the heating equipment of the fuel gas generator.

In an embodiment, the fuel gas generator of the present invention further comprises at least one gas induction facility connected to the air supply port, wherein the at least one gas induction facility is equipped with a heater, and The heat exchange equipment transports the thermal energy to the heating equipment of the fuel gas generator and/or to the heater of the at least one gas induction equipment.

In embodiments, the thermally conductive material includes a catalyst.

In embodiments, the thermally conductive material includes any one or combination of silica sand, iron-based catalysts, copper-based catalysts, and calcium-containing compounds.

In an embodiment, the diameter of the thermally conductive material is 0.1 mm or more and 0.6 mm or less. According to the present invention, the diameter of the thermally conductive material can enhance the efficiency of heat transfer or catalytic reaction.

In embodiments, the silica sand comprises quartz sand, and the iron-based catalyst is triiron tetroxide (Fe ₃ O ₄ ), pentacarbide (Fe ₅ C ₂ ), nickel-iron alloy (Ni—Fe) or iron-nitrogen. containing a doped carbon material (Fe—N—C), the copper-based catalyst being copper/zinc oxide (Cu/ZnO), copper/zinc oxide/aluminum oxide (Cu/ZnO/Al ₂ O ₃ ) or copper/zinc oxide /zirconium oxide (Cu/ZnO/ZrO2) and/or said calcium _- containing compound comprises calcium oxide, calcium hydroxide or calcium carbonate.

In embodiments, the target organics include alkyls, alcohols, esters, ketones, sludge, plastic materials, polarizers, paint residues, printed circuit board (PCB) membrane filtration residues, automobile shreds. Residue (auto shredder residue, ASR), including any one or a combination of agricultural sub-materials.

In an embodiment, the plastic material includes polyurethane (PU) or epoxy resin (epoxy), the plastic material is a polymer, and the secondary agricultural material is any one of rice husk, rice straw, and roadside tree residue. or combinations thereof, and/or the sludge comprises organic sludge or inorganic sludge.

In embodiments, the reactive gas includes any one or combination of air, oxygen gas, nitrogen gas, water vapor, and carbon dioxide. The present invention can prevent the generation of air pollutants such as dioxins by selecting specific reaction gases.

Preferably, the concentration of the oxygen gas is 0% or more and 20% or less. Compared to the disadvantages of the incineration method, which consumes a lot of oxygen and has a large carbon footprint due to the carbon dioxide as the final product, the fuel gas generation method of the present invention is low-oxygen or oxygen-free. In addition to being carried out in an environment, reusable fuel gas can be generated and waste can be recycled, making it possible to realize the concept of a circular economy.

In embodiments, the fuel gas includes any one or combination of hydrogen gas, carbon monoxide and short chain hydrocarbon compounds. Preferably, the short chain hydrocarbon compound comprises any one or combination of methane, ethane and ethylene.

In summary, the fuel gas generator of the present invention allows the thermally conductive material, the target organic matter and the reaction gas to form a fluidized bed, and the mixing effect is achieved by a plurality of cyclone blowing units of at least one second gas induction unit. and by partitioning into a plurality of layers of mixing chambers by means of a first gas induction unit and at least one second gas induction unit, the reaction environment of the pyrolysis process for each layer of mixing chamber is It can be precisely and precisely controlled, can greatly improve the conversion efficiency of waste to fuel or chemical feedstock, and can reduce overall energy consumption, with environmental benefits.

1 is a schematic diagram of an embodiment of a fuel gas generator of the present invention; FIG. Fig. 3 is a three-dimensional view of the first gas induction unit of the fuel gas generator of the present invention; Fig. 3 is a schematic top view of a cyclonic blowing unit of at least one second gas induction unit of the fuel gas generator of the present invention; Fig. 4 is a cross-sectional view of a cyclonic blowing unit of the at least one second gas induction unit of the fuel gas generator of the present invention; FIG. 4 is a schematic diagram of another embodiment of the fuel gas generator of the present invention; 1 is a flowchart of an embodiment of a fuel gas generation method of the present invention; Figure 2 is a flow chart of the fluidization step of the fuel gas generation method of the present invention;

In order to facilitate the description of the embodiments of the present invention, several operating methods are provided below. Those skilled in the art will appreciate the features and effects that the present invention can achieve through the contents of this specification, and that various modifications and changes can be made without departing from the spirit of the present invention. You can easily understand that you are implementing or applying the contents of

[Fuel gas generator]
As shown in FIG. 1, the fuel gas generator 1 of the present invention includes a split tower furnace 10, which includes a containment space 100;
a first gas directing unit 101 having a plurality of spaced perforations 1010; and
including at least one second gas induction unit 102A having a plurality of through holes 1020 and a plurality of cyclonic blowing units 1021;
wherein the plurality of through-holes 1020 are spaced apart from each other, the number of the plurality of through-holes 1020 and the plurality of cyclonic blowing units 1021 are the same, both are eight, and each The cyclone jet unit 1021 has a communication passage 10210, and the communication passage 10210 of each cyclone jet unit 1021 corresponds to each through hole 1020 and communicates with each other. The first gas induction unit 101 and the at least one second gas induction unit 102A are installed in order from the bottom 103 to the top 104 of the layer tower furnace 10, thereby communicating the accommodation space 100 with each other. compartmentalized into multiple layers of mixing chambers,
Among them, the multi-layered mixing chamber includes a lower mixing chamber 1000A located between the bottom 103 of the split-layer furnace 10 and the first gas induction unit 101, the first gas induction unit 101 and the A middle mixing chamber 1000B located between the at least one second gas induction unit 102A, and an upper mixing chamber 1000C located between the top 104 of the split tower furnace 10 and the at least one second gas induction unit 102A. including
an air inlet 105 used to provide reactant gases;
a first material supply port 106 used to provide thermally conductive material;
a second material supply port 107 used to provide the target organic matter;
a first outlet 108 used for discharging the target organic matter after treatment, and the target organic matter after treatment contains the fuel gas;
including a second outlet 109 used for discharging the heat-conducting material,
Among them, the accommodation space 100, the air supply port 105, the first material supply port 106, the second material supply port 107, the first discharge port 108, and the second discharge port 109 communicate with each other. and the air supply port 105 is installed in the lower mixing chamber 1000A,
and a heating facility 11 connected to or surrounding the split tower furnace 10.

In addition, the first material supply port 106 is installed in the upper mixing chamber 1000C, the second material supply port 107 is installed in the middle mixing chamber 1000B, and the first discharge port 108 is installed in the upper mixing chamber 1000C. and the second outlet 109 is installed in the lower mixing chamber 1000A.

As shown in FIG. 2, the first gas induction unit 101 has opposed first and second planes 1011 and 1012, and each perforation 1010 extends from the first plane 1011 to the second plane 1012. , and based on the total area of the first plane 1011, the total cross-sectional area of each of the holes 1010 located on the first plane 1011 is 0.1-1.5%.

FIG. 3 is a top view of the cyclone-type blowing unit 1021. Firstly, each of the cyclone-type blowing units 1021 has a substantially octagonal outer contour, and each side 10211 is provided with a blowing pipe 10212. A total of eight fumaroles 10212 are provided.

Secondly, each fumarole 10212 has a fumarole 102120 and an air intake 102121 communicating with each other, wherein the fumarole 102120 of each fumarole 10212 is the communicating path of the cyclone fumarole unit 1021 to which it belongs. facing 10210 and all pointing counterclockwise.

Third, the fumaroles 102120 of each fumarole 10212 are spaced apart from each other in the communication passage 10210 of the cyclone fumarole unit 1021 to which it belongs, and each fumarole 10212 is connected to the cyclone fumarole unit 1021 to which it belongs. It is installed substantially tangentially to the outer edge of passageway 10210 .

Finally, each fumarole 10212 protrudes away from the communication passage 10210 of the cyclone fumarole unit 1021 to which it belongs. In other words, the inlet 102121 of each fumarole 10212 is located outside the octagon.

As can be seen from FIG. 4, each said cyclonic fumarolic unit 1021 includes a plurality of fumarolic pipes 10212 and thus has a plurality of gas passages 102122 therein.

[Fuel gas generator]
As shown in FIG. 5, the fuel gas generator 1 of the present invention includes two second gas induction units 102A, 102B, and the mixing chamber located between the two second gas induction units 102A, 102B is an intermediate chamber. This is the upper layer mixing chamber 1000D.

In addition, the width of the upper mixing chamber 1000C gradually widens from the at least one second gas induction unit 102B along the direction of the top 104 of the split tower furnace 10, namely the split tower furnace The width of the portion adjacent to the top 104 of 10 is greater than the width of the portion adjacent to the at least one second gas induction unit 102B, thereby effectively reducing the rising speed of the target organic matter and also can be prevented from overflowing the first material supply port 106 or solid granules of target organic matter that have not yet been completely gasified from entering the first discharge port 108 .

Finally, the width of the upper mixing chamber 1000C is greater than the width of the middle and upper mixing chamber 1000D.

[Fuel gas generation method]
As shown in FIG. 6, the fuel gas generation method of the present invention includes a fluidization step S1 and a gasification step S2.

As shown in FIGS. 1 and 6, the fluidization step S1 provides the thermally conductive material, the target organic matter and the reaction gas to the fuel gas generator 1 shown in FIG. The gas forms a fluidized bed in the accommodation space 100. Specifically, quartz sand, waste and nitrogen gas are mixed to form a fluidized bed, and the diameter of the quartz sand is 0.1 mm. It is more than 0.6 mm or less. In the gasification step S2, the fluidized bed is heated to gasify the target organic matter to obtain the fuel gas. Target organic matter is thermally decomposed into fuel gas.

[Fuel gas generation method]
As shown in FIGS. 6 and 7, the fluidization step S1 of the fuel gas generation method of the present invention includes a filling step S1-1, a preheating step S1-2, a material input step S1-3 and a gas induction step S1-4. include.

As shown in FIGS. 1 and 7, the filling step S1-1 fills the accommodation space 100 with the thermally conductive material through the first material supply port . In the preheating step S1-2, the temperature of the housing space 100 is raised by the heating equipment 11. FIG. In the material charging step S1-3, the target organic matter is charged from the second material supplying port 107. FIG. In addition, in the gas induction step S1-4, the reaction gas is introduced from the air supply port 105, and the reaction gas passes through the perforations 1010 of the first gas induction unit 101 and the at least one second gas induction unit 102A. Through the through holes 1020 and the communication passages 10210 of the cyclone blowing units 1021 in order, the reaction gas is passed from the lower mixing chamber 1000A through the middle mixing chamber 1000B and then to the upper mixing chamber 1000C. By reaching it, an ascending gas phase is formed,
and providing cyclonic airflow by introducing the reaction gas from each of the cyclonic blowing units 1021 of the at least one second gas induction unit 102A.

In summary, the fuel gas generation apparatus and method of the present invention have excellent heat conduction and mass transfer effects, and reduce or avoid the use of oxygen gas for pyrolysis, thereby It can generate usable fuel gas, reduce the overall cost of using energy resources, and realize the concept of a circular economy.

Claims (10)

A fuel gas generator comprising:
including a split tower furnace, which
accommodation space,
a first gas induction unit having a plurality of spaced perforations, and at least one second gas induction unit having a plurality of through holes and a plurality of cyclonic blowing units, wherein
The plurality of through-holes are spaced apart from each other, each of the plurality of cyclone-type blowing units has a communication passage, and each of the plurality of cyclone-type blowing units has a communication passage corresponding to each of the plurality of through-holes. correspond to each other and are in communication with each other, and the first gas induction unit and the at least one second gas induction unit are installed in order from the bottom to the top of the split tower furnace. which partitions the containment space into a plurality of layers of mixing chambers in communication with each other, in which:
The plurality of layers of mixing chambers include a lower layer mixing chamber positioned between the bottom of the split-layer furnace and the first gas induction unit, the first gas induction unit and the at least one second gas induction unit an intermediate mixing chamber positioned between and an upper mixing chamber positioned between the top of said split tower furnace and said at least one second gas induction unit;
an air inlet used to provide reactant gases;
a first material supply port used to provide a thermally conductive material;
a second material supply port used to provide organic matter;
used for discharging target organic matter after treatment, said target organic matter after treatment comprising a first outlet containing said fuel gas and a second outlet used for discharging said thermally conductive material, wherein:
The accommodation space, the air supply port, the first material supply port, the second material supply port, the first discharge port, and the second discharge port communicate with each other, and the air supply port communicates with the lower layer mixing A fuel gas generator comprising a heating facility located in the chamber and connected to or surrounding said split tower furnace. The first material supply port is installed in the upper mixing chamber, the second material supply port is installed in the middle mixing chamber, the first discharge port is installed in the upper mixing chamber, and the second discharge port is installed in the lower mixing chamber. 2. The fuel gas generator of claim 1, wherein the width of said upper mixing chamber gradually widens along the direction from said at least one second gas induction unit toward the top of said split tower furnace. The at least one second gas induction unit is a plurality of second gas induction units, and any one mixing chamber positioned between any two of the plurality of second gas induction units adjacent to each other is located in the middle and upper layers 2. The fuel gas generator according to claim 1, wherein the mixing chamber is a mixing chamber, and the width of the upper mixing chamber is greater than the width of the middle and upper mixing chamber. The first gas induction unit has opposed first and second planes, and each of the plurality of perforations extends from the first plane to the second plane, and the total area of the first plane 2. The fuel gas generator according to claim 1, wherein the total cross-sectional area of each of said plurality of perforations located on said first plane is 0.1-1.5% with respect to . each of said plurality of cyclonic fumarolic units has a plurality of fumarolic tubes, wherein each of said plurality of fumarolic tubes has a fumarolic port and an air inlet communicating with each other; 2. The fuel gas generator according to claim 1, wherein each of the fumaroles faces the communication passage of the associated cyclonic fumarole unit and all face in a clockwise or counterclockwise direction to provide a cyclonic airflow. . further comprising transport equipment connected to the second material supply port, at least one gas induction equipment connected to the air supply port, and heat exchange equipment connected to the first discharge port; Wherein, the transportation equipment includes a screw conveyor or an air conveyor, the at least one gas induction equipment includes a Roots blower, a centrifugal blower, a ring blower or an axial flow blower, and the heating equipment includes an electric heater or a boiler. 7. Fuel gas generator according to any one of the preceding claims, comprising a heater or a radio frequency heater, and wherein said first gas induction unit is a reactant gas distribution plate. A fuel gas generation method comprising:
A thermally conductive material, a target organic matter and a reaction gas are provided to the fuel gas generator of claim 1, and the thermally conductive material, the target organic matter and the reaction gas are provided in the containing space in a fluidized bed. and a gasification step of heating the fluidized bed to gasify the target organic matter to obtain the fuel gas. The fluidizing step includes:
A filling step of filling the accommodation space with the thermally conductive material from the first material supply port;
a preheating step of increasing the temperature of the housing space by the heating equipment;
a material introduction step of introducing the target organic matter from the second material supply port; passing through each of the plurality of through-holes of one second gas induction unit and each of the communication passages of the plurality of cyclone type blowing units in order, so that the reaction gas passes from the lower layer mixing chamber through the middle layer mixing chamber; followed by a gas induction step of forming an ascending gas phase by reaching the upper mixing chamber;
and providing a cyclonic airflow by admitting said reactant gas from each of said plurality of cyclonic blowing units of said at least one second gas induction unit. The thermally conductive material includes any one or a combination of silica sand, an iron-based catalyst, a copper-based catalyst, and a calcium-containing compound, and the diameter of the thermally conductive material is 0.1 mm or more and 0.6 mm or less,
The target organic substances include alkyls, alcohols, esters, ketones, sludge, plastic materials, polarizers, paint residues, printed circuit board (PCB) membrane filtration residues, and auto shredders. residue, ASR) and any one or a combination of agricultural subsidiary materials,
and the plastic material includes polyurethane (PU) or epoxy resin (epoxy),
Said secondary agricultural material comprises any one or a combination of rice husk, rice straw, roadside tree residues,
the reactive gas comprises any one or combination of air, oxygen gas, nitrogen gas, water vapor and carbon dioxide ;
and
The fuel gas comprises any one or combination of hydrogen gas, carbon monoxide and short chain hydrocarbon compounds, and the short chain hydrocarbon compound is any one or combination of methane, ethane and ethylene. 9. The method of generating fuel gas according to claim 8, comprising:

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