KR102494498B1 - Biomass gasifier capable of producing biochar - Google Patents

Abstract

The present invention relates to a biomass gasification apparatus capable of producing biochar, comprising: a main body extending in a vertical direction to a predetermined height; a biomass input unit formed at the top of the main body and allowing biomass to be supplied into the main body; a biomass carbonization unit that burns and carbonizes the biomass supplied through the biomass input unit; a biochar discharge unit that discharges the biochar generated in the biomass carbonization unit to the outside; and an oxygen supply means that supplies oxygen into the biomass carbonization unit, wherein the oxygen is uniformly supplied to the biomass to enable uniform combustion of the biomass.

Description

Biomass gasifier capable of producing biochar

The present invention relates to a biomass gasification device that carbonizes biomass such as sawdust, rice husk, or livestock meal, and more particularly, to a biomass gasification device capable of uniformly combusting input biomass and producing biochar.

In Korea, which relies on imports for most of its energy sources, it is essential to establish a long-term energy source supply policy and develop fundamental clean alternative energy that can reduce energy import dependence as much as possible from the perspective of national security or to maintain sustainable economic growth. .

In this reality, biomass is attracting attention as a field of alternative energy that can resolve concerns about the depletion of fossil fuels and environmental pollution. Here, biomass is a term that refers to biological organisms including plants and bacteria, which are produced by photosynthesis of plants and microorganisms receiving solar energy, and animals that feed on them. In other words, biomass resources are starch-based resources such as grains, cellulose-based resources including agricultural products such as forest trees, rice straw, and rice hulls, sugar-based resources such as sugarcane and sugar beets, and organic wastes such as food waste and livestock waste. It has a comprehensive meaning that includes up to.

Here, as part of a plan to effectively utilize waste resources, technology development related to bio-char manufacturing is being actively conducted. Such biochar manufacturing is a technology that can be used by converting organic waste into a high value-added resource by thermally decomposing biomass in the absence of oxygen and carbonizing it into a material having intermediate characteristics between organic matter and activated carbon.

However, in the case of a conventional biomass gasifier, biomass such as rice husk, sawdust or livestock meal having a uniform shape is filled with a certain gap inside the gasifier and can be burned evenly, but biomass with a non-uniform shape has uneven gaps Since it is filled inside the gasifier with , it is not burned uniformly due to non-uniform contact with oxygen. The non-uniform combustion of such biomass adversely affects the quality of biochar to be produced after combustion.

For this reason, a conventional biomass gasification device for producing biochar needs to develop a technology capable of enabling uniform combustion by uniformly supplying oxygen to the biomass filled therein.

Prior Art Document 1: Korean Patent Registration No. 10-2382262 (Announced on April 4, 2022)

Prior Art Document 2: Korean Patent Registration No. 10-1185745 (Announced on September 26, 2012)

The present invention was invented to solve the above problems, and to provide a biomass gasification device capable of producing biochar, which enables uniform combustion of biomass by uniformly supplying oxygen to biomass, for the purpose of providing do,

In order to achieve the above object, the present invention is provided with a receiving space, the main body extending a predetermined height in the vertical direction; a biomass inlet formed on an upper portion of the main body and supplying biomass to the inside of the main body; A biomass carbonization unit formed inside the body and carbonizing the biomass supplied through the biomass input unit by burning it; a biochar discharge unit formed below the biomass carbonization unit on one side of the main body and discharging the biochar generated in the biomass carbonization unit to the outside; And characterized in that it comprises an oxygen supply means for supplying oxygen into the biomass carbonization unit.

Preferably, the oxygen supply unit includes: a movable plate installed to be able to move up and down in a vertical direction inside the main body and having an oxygen supply passage formed therein; a plurality of oxygen supply pipes extending vertically upward from the movable plate, ascending and descending integrally with the movable plate, and communicating with the oxygen supply passage of the movable plate to supply oxygen to the inside of the biomass carbonization unit; and a blower supplying oxygen to the inside of the moving plate so that oxygen is supplied to the inside of the biomass carbonization unit through the oxygen supply pipe.

More preferably, the oxygen supply pipes are arranged to be spaced apart at a predetermined interval along at least one of a radial direction and a circumferential direction based on the center of the moving plate, and the oxygen supply pipes are provided with an oxygen discharge hole at the top. to be

Alternatively, the oxygen supply pipes are arranged to be spaced apart by a predetermined distance along at least one of a radial direction and a circumferential direction based on the center of the moving plate, and the oxygen supply pipes are spaced apart by a predetermined distance from each other along the longitudinal direction, respectively. It is characterized in that it is provided with oxygen discharge holes of.

Preferably, a stopper for limiting the lowering position of the moving plate is installed on the inner lower part of the main body, and a proximity sensor for detecting the stopper is installed on the lower surface of the moving plate to limit the lowering position of the moving plate. , When the movable plate descends to the lowest position by the stopper and the proximity sensor, the oxygen supply pipe is located below the biochar discharge part, and the biochar is discharged only when the movable plate descends to the lowest position. It is characterized in that the part works.

On the other hand, the biomass input unit: a work platform installed around the upper portion of the main body on which a worker can be located; an input duct inclined downward toward the biomass carbonization unit and into which biomass is introduced; an air cylinder installed inside the input duct and pushing biomass stagnant inside the input duct toward the biomass carbonization unit by operation; and an opening/closing door provided at one side of the upper portion of the main body to be capable of being opened and closed so that an operator can flatten the biomass filled therein using a mechanism.

In addition, the biomass supply unit further includes a biomass supply means for supplying biomass to the biomass input unit, wherein the biomass supply means includes: a biomass transfer screw that transfers the biomass in a horizontal direction from the lower side of the main body; a biomass input hopper installed above the biomass conveying screw and supplying biomass to the biomass conveying screw; an elevating frame disposed between the biomass conveying screw and the body, extending vertically higher than the body, and having rotation shafts at upper and lower portions, respectively; A belt or chain that is connected between a pair of the rotational shafts and performs a reciprocating motion in a vertical direction; And coupled to the belt or chain at a predetermined distance from each other, receiving the biomass transported by the biomass transfer screw, and lifting the biomass integrally with the belt or chain in a vertical direction by rotation of the rotation shaft. It is characterized in that it comprises a plurality of supply boxes for supplying biomass to the input unit.

In addition, the biomass carbonization unit: an ignition heater installed on an upper side surface of the main body and heating the oxygen supplied from the oxygen supply means to ignite the biomass during operation; a temperature sensor installed on an inner upper portion of the main body and measuring a temperature inside the biomass carbonization unit; And it is installed on the inner upper part of the main body, characterized in that it comprises a level sensor for measuring the amount of biomass supplied to the inside of the biomass carbonization unit.

In addition, the biochar discharge unit includes: a support plate disposed under the biomass carbonization unit and supporting the biochar generated in the biomass carbonization unit; a discharge door installed to be openable and openable on the side of the main body at the same height as the support plate; a rotary agitation mechanism installed on the support plate, rotating about a central axis to agitate the biochar and discharging the biochar toward the discharge door; a biochar transport screw extending from the discharge door to the outside of the main body and horizontally transporting the biochar discharged through the discharge door; and an air cylinder installed on one side of the biochar conveying screw and opening and closing the discharge door by operation.

Additionally, a gas combustion means for burning incomplete combustion gas generated from the biomass carbonization unit is further included, and the gas combustion means includes: a combustion furnace extending in a vertical direction at a predetermined height; a gas transfer pipe communicating the biomass carbonization unit and the combustion furnace; a blower installed between the combustion furnace and the gas transport pipe and operating to introduce incomplete combustion gas of the biomass carbonization unit into the combustion furnace through the gas transport pipe; a burner installed inside the combustion furnace to heat and burn incomplete combustion gas supplied into the combustion furnace; a temperature sensor for measuring the internal temperature of the furnace; and a drain pipe installed on a downstream side of the gas transport pipe and discharging condensed water generated by the temperature drop of the gas flowing into the combustion furnace through the gas transport pipe.

According to the present invention, the oxygen supply means is configured to be able to be raised and lowered, and oxygen can be supplied while descending from the upper part to the lower part of the biomass carbonization unit. By the operation of the oxygen supply means, the biomass burned and carbonized in the biomass carbonization unit is uniformly burned and carbonized to produce biochar of uniform quality.

1 is a perspective view showing a biomass gasification device capable of producing biochar according to the present invention;
2 is a side cross-sectional view showing a biomass gasification apparatus capable of producing biochar according to the present invention;
3 is a plan view showing a biomass gasification device capable of producing biochar according to the present invention;
4 is a cross-sectional plan view of a biomass gasification device capable of producing biochar according to the present invention, showing the arrangement of an oxygen supply pipe of an oxygen supply means.

Hereinafter, a preferred embodiment of a biomass gasification device capable of producing biochar according to the present invention will be described with reference to the accompanying drawings. For reference, in describing the present invention below, the terms referring to the components of the present invention are named in consideration of the functions of each component, so they should not be understood as limiting the technical components of the present invention. It will be.

1 to 4, the biomass gasification device capable of producing biochar according to the present invention is a device for generating bio-char by carbonizing biomass such as sawdust, rice husk, or livestock meal, and includes a main body 100 ), the biomass input unit 110 provided on the upper part of the body 100, the biomass carbonization unit 120 provided inside the body 100, and the biochar discharge unit provided on one side of the body 100 ( 130), and an oxygen supply means 140.

The main body 100 has an accommodation space therein, and extends to a predetermined height to have a tower-shaped structure. The main body 100 may be a hexahedron-shaped structure, but may preferably be a cylindrical structure for uniform combustion.

The biomass input unit 110 is formed on the upper portion of the main body 100 and serves to supply biomass such as sawdust, rice hulls or livestock manure into the main body 100 . The biomass input unit 110 may be formed as a cone-shaped structure as a whole, and has an input duct 111 into which biomass is injected at one side.

The biomass carbonization unit 120 is formed below the biomass input unit 110 inside the body 100, and carbonizes the biomass introduced into the body 100 through the biomass input unit 110 by burning it. play a role in The biomass carbonization unit 120 is formed in a space between the biomass input unit 110 from an intermediate height based on the overall height of the main body 100, and consists of a biomass combustion and carbonization space.

The biochar discharge unit 130 is formed below the biomass carbonization unit 120, that is, at about the middle height of the main body 100. The biochar discharge unit 130 serves to discharge biochar produced by combustion and carbonization in the biomass carbonization unit 120 to the outside of the main body 100 .

The oxygen supply means 140 supplies oxygen into the biomass carbonization unit 120 so that the biomass can be uniformly burned. Specifically, the oxygen supply means 140 is a movable plate 141 installed to be able to vertically ascend and descend inside the main body 100, and extends vertically upward from the movable plate 141 to be integral with the movable plate 141. It is configured to include a plurality of oxygen supply pipes 142 that ascend and descend, and a blower 143 for supplying oxygen to the oxygen supply pipe 142 side.

The moving plate 141 may be formed in a disk shape to correspond to the horizontal cross-sectional shape of the main body 100 . The moving plate 141 is supported by a plurality of guide frames 101 extending vertically inside the main body 100 so as to be able to move up and down, and along the guide frame 101 by driving and controlling the servo motor 102. ascends and descends. In addition, the moving plate 141 has an oxygen supply passage formed therein, and oxygen supplied through the blower 143 is transferred to the side of the oxygen supply pipe 142 via the oxygen supply passage of the moving plate 141 .

The plurality of oxygen supply pipes 142 communicate with the oxygen supply passage of the moving plate 141 and supply oxygen to the inside of the biomass carbonization unit 120 by the operation of the blower 143 .

The blower 143 is installed on the lower outer side of the body 100. The blower 143 and the moving plate 141 communicate with each other through a connecting pipe 144, and the connecting pipe 144 is made of a fixed pipe outside the main body 100 and inside the main body 100. It is made of a pipe made of a flexible material to allow movement of the moving plate 141. Here, the blower 143 is preferably a ring blower capable of producing a large lift at a small flow rate and having excellent low flow/low pressure characteristics.

As described above, in the biomass gasification device capable of producing biochar according to the present invention, the oxygen supply pipe 142 of the oxygen supply unit 140 is configured to be able to move up and down inside the body 100, so that the biomass carbonization unit ( 120) may supply oxygen while descending from the top to the bottom. By the operation of the oxygen supply unit 140, the biomass burned and carbonized in the biomass carbonization unit 120 is uniformly burned and carbonized to produce biochar of uniform quality.

Preferably, the oxygen supply pipes 142 of the oxygen supply unit 140 may be spaced apart at regular intervals in a radial direction and/or a circumferential direction based on the center of the moving plate 141 . In addition, the oxygen supply pipes 142 are provided with oxygen discharge holes at the upper ends.

When the moving plate 141 is raised to the middle height of the main body 100 and the oxygen discharge holes of the oxygen supply pipes 142 are positioned at the top of the biomass carbonization unit 120, the biomass input unit 110 Biomass is introduced into the biomass carbonization unit 120 by the. Then, when the biomass is completely filled in the biomass carbonization unit 120, combustion starts and the oxygen supply means 140 starts to descend. Then, the oxygen discharge hole of the oxygen supply pipe 142 gradually descends from the top of the biomass carbonization unit 120 to the lowest end of the biomass carbonization unit 120, and at the same time, the biomass carbonization unit 120 oxygen is supplied internally. Accordingly, the biomass filled in the biomass carbonization unit 120 may be evenly burned and carbonized from the top to the bottom.

Alternatively, the oxygen supply pipes 142 of the oxygen supply means 140 are arranged to be spaced apart at regular intervals along the radial direction and/or the circumferential direction with respect to the center of the moving plate 141, and the oxygen supply pipes 142 may each have a plurality of oxygen discharge holes spaced apart from each other along the longitudinal direction.

Meanwhile, a stopper 145 for limiting the lowering position of the moving plate 141 is installed on the inner lower part of the main body 100 . In addition, a proximity sensor 146 for detecting the stopper 145 is installed on the side and/or bottom surface of the moving plate 141. By this configuration, the biomass carbonization unit 120 moves during combustion and carbonization work The lowering position of the plate 141 may be limited.

Here, when the moving plate 141 descends to the lowest position of the body 100 by the stopper 145 and the proximity sensor 146, the oxygen supply pipe 142 is lower than the biochar outlet 130. will be located In addition, the biochar discharge unit 130 may operate only when the moving plate 141 descends to the lowermost position of the main body 100 .

As such, the stopper 145 and the proximity sensor 146 sense the lowered position of the moving plate 141 and allow the operation of the biochar discharge unit 130, thereby allowing the operation of the biochar discharge unit 130 to supply oxygen. It can be prevented from being obstructed by the pipe 142.

Preferably, the biomass input unit 110 includes an input duct 111, a work platform 112, an air cylinder 113, and an opening and closing door 114. The input duct 111 is inclined downward toward the biomass carbonization unit 120 and is an inlet through which biomass is introduced into the main body 100 . The work platform 112 is installed around the top of the main body 100 and serves to allow an operator to be positioned. The air cylinder 113 is installed inside the input duct 111, opens and closes the input door 111a provided at the top of the input duct 111 during operation, and removes stagnant biomass inside the input duct 111. It serves to push the biomass carbonization unit 120 side. In addition, the opening and closing door 114 is provided to be able to open and close on one side of the upper portion of the conical body 100, allowing a worker to flatten the biomass filled therein using a tool.

Additionally, the biomass gasification device capable of producing biochar according to the present invention further includes a biomass supply means 200 for supplying biomass to the biomass input unit 110 . The biomass supply unit 200 includes a biomass transfer screw 210, a biomass input hopper 220, a lifting frame 230, a belt or chain 240, and a plurality of supply boxes 250.

First, the biomass transfer screw 210 transfers biomass in a horizontal direction from the lower side of the main body 100 . The biomass input hopper 220 is installed above the biomass transfer screw 210 and supplies biomass to the biomass transfer screw 210 . The elevating frame 230 is disposed between the biomass conveying screw 210 and the body 100, extends vertically higher than the body 100, and has rotation shafts 231 at upper and lower portions, respectively. The belt or chain 240 is connected between a pair of rotational shafts 231 and is configured to perform a reciprocating movement in a vertical direction. The plurality of supply boxes 250 are spaced apart from each other at regular intervals and coupled to the belt or chain 240, receive the biomass transferred by the biomass transfer screw 210, and rotate the belt by the rotation of the rotation shaft 231. Alternatively, it serves to supply biomass to the biomass input unit 110 while moving up and down in the vertical direction integrally with the chain 240 .

In addition, the biomass carbonization unit 120 includes an ignition heater 121 and a temperature sensor 122 . First, the ignition heater 121 is installed on the upper side of the main body 100 as an ignition means. During operation, the ignition heater 121 heats the oxygen supplied from the oxygen supply pipes 142 of the oxygen supply unit 140 to ignite the biomass. The temperature sensor 122 is installed on the inner upper part of the main body 100, precisely on the side of the biomass input unit 110, and measures the temperature inside the biomass carbonization unit 120. According to the measurement result of the temperature sensor 122, the operation of the blower 143 of the oxygen supply unit 140 may be controlled to appropriately adjust the oxygen supply amount.

Additionally, the biomass carbonization unit 120 may further include a level sensor 123 . The level sensor 123 is installed on the inner upper part of the main body 100, preferably in the input duct 111, and measures the amount of biomass supplied to the inside of the biomass carbonization unit 120. Here, the level sensor 123 is a round rod of a predetermined length extending into the biomass carbonization unit 120 through the input duct 111, and a sensor installed at the lower end of the round rod to contact the biomass inside the main body 100. It may include a portion and a flange portion that is in close contact with the inner periphery of the input duct 111 to seal the input duct 111 and the round bar. By the level sensor 123, it is possible to detect whether the biomass is filled inside the carbonization unit 120, and the operation of the ignition heater 121 and the oxygen supply unit 140 can be started according to the detection result.

In addition, the biochar discharge unit 130 includes a support plate 131, a discharge door 132, a rotary stirring mechanism 133, a biochar transfer screw 134, and an air cylinder 135. First, the support plate 131 is disposed under the biomass carbonization unit 120 and serves to support the biochar generated in the biomass carbonization unit 120 . The discharge door 132 is openable and openable on the side of the main body 100 at the same height as the support plate 131, so that the biochar generated in the biomass carbonization unit 120 can be discharged to the outside of the main body 100. do. The rotational agitation mechanism 133 is rotatably installed on the support plate 131 and rotates about a central axis to stir the biochar and discharge the biochar toward the discharge door 132 at the same time. The biochar transfer screw 134 extends from the discharge door 132 to the outside of the main body 100 and transfers the biochar discharged through the discharge door 132 in a horizontal direction. The air cylinder 135 is installed on one side of the biochar transfer screw 134 and serves to open and close the discharge door 132 by operation.

Additionally, the biomass gasifier capable of producing biochar according to the present invention may further include a gas combustion means 300 for burning incomplete combustion gas generated from the biomass carbonization unit 120 . Specifically, the gas combustion means 300 includes a furnace 310, a gas transfer pipe 320, a blower 330, a burner 340, a temperature sensor 350, and a drain pipe 360. .

The combustion furnace 310 is a cylindrical structure extending in a vertical direction to a predetermined height. The gas transport pipe 320 communicates the biomass carbonization unit 120 and the combustion furnace 310 . The gas transport pipe 320 extends horizontally from the upper part of the main body 100 and then vertically downward toward the lower side of the furnace 310 . The blower 330 is installed between the combustion furnace 310 and the gas transfer pipe 320, and operates to introduce incomplete combustion gas of the biomass carbonization unit 120 into the combustion furnace through the gas transfer pipe 320. . The burner 340 is installed inside the furnace 310 and heats and burns the incomplete combustion gas supplied inside the furnace 310 . The temperature sensor 350 is installed on one side of the furnace 310 to measure the temperature inside the furnace 310 . The temperature sensors 350 are respectively installed at the bottom and top of the furnace 310 to measure the temperature inside the furnace 310, and control the operation of the burner 340 according to the measurement result of the temperature sensor 350. It can be. The drain pipe 360 is installed on the downstream side of the gas transport pipe 320, precisely at the lower end of the gas transport pipe 320 extending vertically downward, and flows into the furnace 310 through the gas transport pipe 320. It plays a role in discharging condensate produced by the temperature drop of the gas being cooled.

By the gas combustion means 300, it is possible to prevent the incomplete combustion gas generated in the biomass carbonization unit 120 from leaking out and contaminating the environment.

The embodiments of the present invention described above are only exemplarily showing the technical spirit of the present invention, and the protection scope of the present invention should be construed according to the following claims. In addition, those skilled in the art to which the present invention belongs will be able to make various modifications and variations without departing from the essential characteristics of the present invention, and all technical ideas within the equivalent scope of the present invention It should be interpreted as being included in the scope of rights.

100: body 101: guide frame
102: servo motor 110: biomass input unit
111: input duct 111a: input door
112: work platform 113: air cylinder
114: opening and closing door 120: biomass carbonization unit
121: ignition heater 122: temperature sensor
123: level sensor 130: biomass discharge unit
131: support plate 132: discharge door
133: rotary stirring mechanism 134: biochar transfer screw
135: air cylinder 140: oxygen supply means
141: moving plate 142: oxygen supply pipe
143: blower 144: connecting pipe
145: stopper 146: proximity sensor
200: biomass supply means 210: biomass transfer screw
220: biomass input hopper 230: lifting frame
231: axis of rotation 240: belt or chain
250: supply box 300: gas combustion means
310: combustion furnace 320: gas transfer pipe
330: blower 340: burner
350: temperature sensor 360: drain pipe

Claims (10)

A body having an accommodation space and extending in a vertical direction to a predetermined height;
a biomass inlet formed on an upper portion of the main body and supplying biomass to the inside of the main body;
A biomass carbonization unit formed inside the body and carbonizing the biomass supplied through the biomass input unit by burning it;
a biochar discharge unit formed below the biomass carbonization unit on one side of the main body and discharging the biochar generated in the biomass carbonization unit to the outside; and
and an oxygen supply means for supplying oxygen into the biomass carbonization unit, wherein the oxygen supply means:
a movable plate installed to be able to ascend and descend in the vertical direction inside the main body and having an oxygen supply passage formed therein;
a plurality of oxygen supply pipes extending vertically upward from the movable plate, ascending and descending integrally with the movable plate, and communicating with the oxygen supply passage of the movable plate to supply oxygen to the inside of the biomass carbonization unit; and
A biomass gasification device capable of producing biochar, characterized in that it comprises a blower supplying oxygen to the inside of the moving plate so that oxygen is supplied to the inside of the biomass carbonization unit through the oxygen supply pipe.
According to claim 1,
The oxygen supply pipes are arranged to be spaced apart at a predetermined interval along at least one of a radial direction and a circumferential direction based on the center of the moving plate,
Biomass gasification device capable of producing biochar, characterized in that the oxygen supply pipes are provided with oxygen discharge holes at the top.
According to claim 1,
The oxygen supply pipes are arranged to be spaced apart at a predetermined interval along at least one of a radial direction and a circumferential direction based on the center of the moving plate,
The biomass gasification device capable of producing biochar, characterized in that each of the oxygen supply pipes has a plurality of oxygen discharge holes spaced apart from each other at a predetermined interval along the longitudinal direction.
According to claim 1,
A stopper for limiting the lowering position of the moving plate is installed on the inner lower part of the main body, and a proximity sensor for detecting the stopper is installed on the lower surface of the moving plate to limit the lowering position of the moving plate,
When the moving plate is lowered to the lowest position by the stopper and the proximity sensor, the oxygen supply pipe is located below the biochar outlet,
Biomass gasification device capable of producing biochar, characterized in that the biochar discharge unit operates only when the moving plate is lowered to the lowest position.
According to claim 1,
The biomass input unit:
A work platform installed around the upper part of the main body on which an operator can be located;
an input duct inclined downward toward the biomass carbonization unit and into which biomass is introduced;
an air cylinder installed inside the input duct, opening and closing an input door provided at an upper portion of the input duct by operation, and pushing biomass stagnant inside the input duct toward the biomass carbonization unit; and
A biomass gasification device capable of producing biochar, characterized in that it comprises an opening and closing door provided on one side of the upper part of the main body to be openable and openable so that an operator can flatten the biomass filled therein using a tool.
According to claim 1,
Further comprising a biomass supply means for supplying biomass to the biomass input unit, wherein the biomass supply means:
a biomass conveying screw for conveying biomass in a horizontal direction from the lower side of the main body;
a biomass input hopper installed above the biomass conveying screw and supplying biomass to the biomass conveying screw;
an elevating frame disposed between the biomass conveying screw and the body, extending vertically higher than the body, and having rotation shafts at upper and lower portions, respectively;
A belt or chain that is connected between a pair of the rotational shafts and performs a reciprocating motion in a vertical direction; and
The biomass input is coupled to the belt or chain at a predetermined distance from each other, receives the biomass transported by the biomass transfer screw, and moves up and down in a vertical direction integrally with the belt or chain by the rotation of the rotating shaft. Biomass gasification device capable of producing biochar, characterized in that it comprises a plurality of supply boxes for supplying biomass to the unit.
According to claim 1,
The biomass carbonization unit:
an ignition heater installed on an upper side surface of the main body and heating the oxygen supplied from the oxygen supply means to ignite the biomass during operation;
a temperature sensor installed on an inner upper portion of the main body and measuring a temperature inside the biomass carbonization unit; and
A biomass gasification device capable of producing biochar, characterized in that it includes a level sensor installed on the inner upper part of the main body and measuring the amount of biomass supplied to the inside of the biomass carbonization unit.
According to claim 1,
The biochar discharge unit:
a support plate disposed under the biomass carbonization unit and supporting the biochar generated in the biomass carbonization unit;
a discharge door installed to be openable and openable on the side of the main body at the same height as the support plate;
a rotary agitation mechanism installed on the support plate, rotating about a central axis to agitate the biochar and discharging the biochar toward the discharge door;
a biochar transport screw extending from the discharge door to the outside of the main body and horizontally transporting the biochar discharged through the discharge door; and
A biomass gasification device capable of producing biochar, characterized in that it comprises an air cylinder installed on one side of the biochar transfer screw and opening and closing the discharge door by operation.
According to claim 1,
Further comprising a gas combustion means for burning incomplete combustion gas generated from the biomass carbonization unit, wherein the gas combustion means:
a combustion furnace extending at a predetermined height in the vertical direction;
a gas transfer pipe communicating the biomass carbonization unit and the combustion furnace;
a blower installed between the combustion furnace and the gas transport pipe and operating to introduce incomplete combustion gas of the biomass carbonization unit into the combustion furnace through the gas transport pipe;
a burner installed inside the combustion furnace to heat and burn incomplete combustion gas supplied into the combustion furnace;
a temperature sensor for measuring the internal temperature of the furnace; and
A drain pipe installed on the downstream side of the gas transfer pipe and discharging condensate generated by the temperature drop of the gas flowing into the combustion furnace through the gas transfer pipe; Mass gasifier. delete

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