CN113563930A

CN113563930A - System for be used for biomass gasification electricity generation

Info

Publication number: CN113563930A
Application number: CN202110836128.1A
Authority: CN
Inventors: 王宁
Original assignee: Guangzhou Qihang Environmental Protection Technology Co ltd
Current assignee: Fujian Kaisheng Biomass Power Generation Co ltd
Priority date: 2021-07-23
Filing date: 2021-07-23
Publication date: 2021-10-29
Anticipated expiration: 2041-07-23
Also published as: CN113563930B

Abstract

The invention relates to the field of biomass energy power generation, in particular to a system for biomass gasification power generation, which comprises a processing bottom plate, wherein a biomass raw material feeding groove is fixedly arranged above one side of the processing bottom plate, a first fixing plate is fixedly arranged above the processing floor and close to the raw material feeding groove, a raw material processing cavity is fixedly arranged above the first fixing plate, a combustible gas first conveying pipeline is arranged above the raw material processing cavity, a pumping pump is arranged at the other end of the first conveying pipeline, a combustible gas processing mechanism is arranged below the pumping pump and on the processing bottom plate, a water tank is arranged on one side, far away from a raw material inlet notch, above the processing bottom plate, a catalyst storage cavity is fixedly arranged above the water tank, a second pumping pump is fixedly arranged above the processing bottom plate and far away from the combustible gas processing mechanism, two pipeline interfaces at one end of the second pumping pump are respectively connected into the combustible gas processing mechanism, and a fuel gas power generation mechanism is arranged at the other end of the second pumping pump. The biomass raw material can be processed into combustible gas and power generation can be realized.

Description

System for be used for biomass gasification electricity generation

Technical Field

The invention relates to the field of biomass energy power generation, in particular to a system for biomass gasification power generation.

Background

The biomass energy conversion technology can be used for efficiently utilizing biomass energy, producing various clean fuels, replacing coal, petroleum, natural gas and the like to produce electric power, thereby reducing the dependence on mineral energy, protecting national energy resources and reducing the pollution to the environment caused by measurable consumption. At present, countries in the world, especially developed countries, are all dedicated to developing efficient and pollution-free biomass energy utilization technology so as to achieve the purposes of protecting mineral resources, guaranteeing national energy safety, realizing carbon dioxide emission reduction and maintaining national economic sustainable development. At present, most biomass power generation mechanisms generate electricity by directly burning biomass or burn the biomass and fossil fuel in a mixing way, but the phenomenon that tar generated in the production process cannot be processed and pollution gas such as carbon monoxide is generated generally occurs, so a system for biomass gasification power generation is designed aiming at the phenomenon, the device can efficiently process and secondarily utilize the tar generated in the production process, and meanwhile, the combustible pollution gas of the carbon monoxide can be utilized to generate electricity.

Disclosure of Invention

The invention aims to solve the problems in the prior art, and provides a system for biomass gasification power generation, which can efficiently crack and reutilize tar generated in the production process, and can utilize combustible polluted gas of carbon monoxide to generate power.

In order to achieve the purpose, the invention adopts the following technical scheme: a system for biomass gasification power generation comprises a processing bottom plate, a biomass raw material feeding groove is fixedly installed above one side of the processing bottom plate, a first fixing plate is fixedly arranged above the processing floor close to the raw material feeding groove, a raw material processing cavity is fixedly arranged above the first fixing plate, a combustible gas first conveying pipeline is arranged above the raw material processing cavity, a pumping pump is arranged at the other end of the first conveying pipeline, a combustible gas processing mechanism is arranged below the pumping pump and on the processing bottom plate, a water tank is arranged on one side of the upper portion of the processing bottom plate far away from the raw material feeding groove, a catalyst storage cavity is fixedly arranged above the water tank, a second pumping pump is fixedly arranged above the processing bottom plate far away from the combustible gas processing mechanism, two pipeline interfaces at one end of the second pumping pump are respectively connected into the combustible gas processing mechanism, and a fuel storage cavity of a power generation mechanism is fixedly arranged above the processing bottom plate and close to the first fixing plate and the combustible gas power generation mechanism.

Preferably, the processing bottom plate's inside sets firmly high temperature resistant conveying mechanism, conveying mechanism's both sides are equipped with two raw materials respectively and prevent falling the backplate, and wherein one the raw materials prevents falling and has set firmly the trigger block on the backplate, the radial both ends of the interior ring raw materials processing chamber of first fixed plate are equipped with two cavities, set firmly two engaged with gears in every cavity, the excircle a week of every gear evenly be equipped with eight with the contact piece that the trigger block contacted in the radial direction.

Preferably, two sealing plates capable of sliding up and down are arranged on one side of each of the two chambers close to the raw material processing chamber, a connecting and fixing member is fixedly arranged between the two sealing plates, seven atomizing spray heads are uniformly arranged in the processing bottom plate in the direction away from the raw material processing chamber and above the raw material falling-preventing protection plate, the seven atomizing spray heads are all connected into a water conveying pipeline fixedly arranged in the processing bottom plate above the seven atomizing spray heads, the other end of the water conveying pipeline is connected into the water tank, and a drawable slag collecting assembly is arranged below the conveying mechanism and on the processing bottom plate.

Preferably, the disintegrating slag collecting assembly comprises a cambered disintegrating slag splash-proof guard plate close to one side of the circular end face of the conveying mechanism, an arc-shaped tar scraper blade is further arranged on the side of the cambered disintegrating slag splash-proof guard plate, a fixed stop block is arranged on one side, far away from the cambered disintegrating slag splash-proof guard plate, of the arc-shaped tar scraper blade, and the fixed stop block is used for limiting the rotation of the arc-shaped tar scraper blade.

Preferably, two-layer filtering mechanism has set firmly above the processing chamber of raw materials, the first filter that is located the below and the second filter in its top respectively, the one end of second suction pump is equipped with respectively and inserts the combustible gas second pipeline and the tar of combustible gas processing mechanism produce gaseous pipeline, the inside tar granule that is equipped with of combustible gas processing mechanism solidifies the chamber, tar granule solidifies the chamber below and is equipped with tar processing chamber, be equipped with two sets ofly respectively at both ends in the tar granule solidifies the chamber, four catalyst nozzles of every group, tar granule solidifies the chamber intermediate position and is equipped with the rotation stationary blade, it is connected with a spiral helicine gas delivery subassembly to rotate the stationary blade below.

Preferably, the gas delivery subassembly includes that the a week outside has set firmly the flight, it runs through to rotate the stationary blade tar granule solidifies the chamber up end, oil granule solidify the chamber up end with it rotates stationary blade fixedly connected with and rotates the connection piece, it is equipped with the hold-in range on the connection piece to rotate, the hold-in range other end is connected with the output transmission of a motor, rotate the stationary blade with tar granule solidifies chamber up end space position and is equipped with the catalyst feed inlet, the catalyst feed inlet is through running through the catalyst pipeline who rotates the connection piece with the chamber is stored to the catalyst links to each other.

Preferably, the tar processing chamber with the tar granule solidifies the chamber and is connected through setting firmly the tar collecting plate between the two, tar collecting plate both ends are the arc, and the centre is horizontal design set up tar infiltration mouth on two arc terminal surfaces of tar collecting plate respectively, in the tar processing chamber with tar infiltration mouth zonulae occludens department is equipped with and separates the temperature dustcoat, be equipped with rotatable tar guide bar in separating the temperature dustcoat, tar guide bar and tar processing chamber lateral wall rotate and are connected, evenly distributed has the stirring rod on the tar guide bar, tar processing chamber bottom is equipped with two high temperature heating rod, high temperature heating rod is through installing the heater work of handling the bottom plate top, combustible gas passes through combustible gas second pipeline and lets in the tar granule solidifies the chamber in the tar processing chamber in the tar produces gas pipeline and lets in through tar production gas pipeline the second pump In the pump, the second pumping pump mixes the combustible gas and the gas generated after tar treatment and then feeds the mixture into the gas power generation mechanism for power generation, and the fuel storage cavity sends the fuel to the gas power generation mechanism through the fuel conveying pipeline for biomass gasification power generation.

Has the advantages that: the invention provides a system for biomass gasification power generation through improvement. Compared with the prior art, the method has the following improvements and advantages:

1, the device gasifies the biomass to generate combustible gas for power generation, protects national energy resources and has important significance in reducing pollution to the environment caused by energy consumption.

2, the problem of tar pollutant generation in the biomass power generation production process is effectively solved through the cracking treatment and secondary utilization of tar in the device.

3, the serious problem of generating polluted gas in the biomass energy power generation process can be effectively solved by treating and utilizing the carbon monoxide in the device process.

At present, the biomass gasification technology is the most practical one in the biomass thermochemical conversion technology, and the development of biomass gasification for power generation is an important way for constructing a stable, economic, clean and safe energy supply system and breaking through the restriction of economic and social development on resource and environment.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a top view of the present invention;

FIG. 3 is a side view of the present invention;

FIG. 4 is a cross-sectional view taken along line A-A of FIG. 3;

FIG. 5 is a cross-sectional view taken along line B-B of FIG. 1;

FIG. 6 is an enlarged view of a portion of FIG. 4 at C;

in the figure: a processing bottom plate 1, a raw material feeding groove 2, a first fixing plate 10, a raw material processing chamber 3, a first conveying pipeline 4, a suction and compression pump 6, a combustible gas processing mechanism 20, a water tank 36, a catalyst storage chamber 8, a second suction and compression pump 11, a gas power generation mechanism 14, a fuel storage chamber 12, a conveying mechanism 29, a raw material falling prevention guard plate 54, a trigger block 26, a chamber 28, a gear 25, a contact block 27, a closing plate 55, a connecting fixing member 24, an atomizing nozzle 17, a water conveying pipeline 33, a slag collecting assembly 56, a slag splash guard plate 32, a tar scraper 31, a fixing stopper 30, a first filter plate 22, a second filter plate 21, a second conveying pipeline 15, a tar generation gas conveying pipeline 16, a tar particle solidification chamber 57, a tar processing chamber 58, a catalyst nozzle 44, a rotating fixing plate 48, a gas conveying assembly 46, a spiral plate 47 and a rotating connecting sheet 49, the device comprises a synchronous belt 51, a motor 52, a catalyst feeding port 50, a catalyst conveying pipeline 39, a catalyst storage cavity 8, a tar collecting plate 45, a tar seepage port 43, a heat insulation outer cover 40, a tar guide rod 41, a stirring rod 42 and a high-temperature heating rod 35.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

In the description of the present invention, it should be noted that the terms "inside", "below", and the like refer to orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention conventionally place when used, and are used only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

With reference to the attached figures 1-6, a system for biomass gasification power generation comprises a processing bottom plate 1, a biomass raw material feeding groove 2 is fixedly installed above one side of the processing bottom plate 1, a first fixing plate 10 is fixedly installed above the processing bottom plate 1 and close to the raw material feeding groove 2, a raw material processing chamber 3 is fixedly installed above the first fixing plate 10, a combustible gas first conveying pipeline 4 is arranged above the raw material processing chamber 3, a pumping pump 6 is arranged at the other end of the first conveying pipeline 4, a combustible gas processing mechanism 20 is arranged below the pumping pump 6 and on the processing bottom plate 1, a water tank 36 is arranged above the processing bottom plate 1 and far away from the raw material feeding groove 2, a catalyst storage chamber 8 is fixedly arranged above the water tank 36, a second pumping pump 11 is fixedly arranged above the processing bottom plate 1 and far away from the combustible gas processing mechanism 20, two pipeline interfaces at one end of the second pumping pump 11 are respectively connected into the combustible gas processing mechanism 20, the other end of the second pumping pump is provided with a fuel gas generating mechanism 14, and a generating mechanism fuel storage cavity 12 is fixedly arranged above the processing bottom plate 1 and close to the first fixing plate 10 and the fuel gas generating mechanism 14.

Further, the inside of handling bottom plate 1 sets firmly high temperature resistant conveying mechanism 29, and conveying mechanism 29's both sides are equipped with two raw materials respectively and prevent falling backplate 54, and wherein set firmly trigger block 26 on preventing falling the backplate of one raw materials, and the radial both ends of the interior ring raw materials processing chamber 3 of first fixed plate 10 are equipped with two cavities 28, sets firmly two engaged with gears 25 in every cavity 28, and the excircle a week of every gear 25 evenly is equipped with eight contact blocks 27 that contact with trigger block 26 in the radial direction.

Furthermore, two closing plates 55 capable of sliding up and down are arranged on one side of the two chambers 28 close to the raw material processing cavity 3, a connecting and fixing member 24 is fixedly arranged between the two closing plates 55, seven atomizing nozzles 17 are uniformly arranged in the processing bottom plate 1 above the raw material falling-preventing protection plate 54 and far away from the raw material processing cavity 3, the seven atomizing nozzles 17 are all connected into a water conveying pipeline 33 fixedly arranged in the processing bottom plate 1 above the seven atomizing nozzles, the other end of the water conveying pipeline 33 is connected into a water tank 36, and a drawable slag collecting assembly 56 is arranged below the conveying mechanism 29 and on the processing bottom plate 1.

Further, the slag collecting component 56 comprises an arc-shaped slag splash-proof guard plate 32 which is arranged on one side of a circular end face close to the conveying mechanism 29, an arc-shaped tar scraper 31 is further arranged on the side edge of the arc-shaped slag splash-proof guard plate 32, a fixed stop block 30 is arranged on one side, far away from the arc-shaped slag splash-proof guard plate 32, of the arc-shaped tar scraper 31, and the fixed stop block 30 limits the rotation of the arc-shaped tar scraper 31.

Further, two layers of filtering mechanisms are fixedly arranged above the raw material processing chamber 3, namely a first filtering plate 22 positioned below and a second filtering plate 21 positioned above the filtering mechanisms, one end of the second pumping pump 11 is respectively provided with a combustible gas second conveying pipeline 15 connected into the combustible gas processing mechanism 20 and a tar generation gas conveying pipeline 16, a tar particle solidification chamber 57 is arranged inside the combustible gas processing mechanism 20, a tar processing chamber 58 is arranged below the tar particle solidification chamber 57, two groups of tar particles are respectively arranged at two ends of the tar particle solidification chamber 57, four catalyst spray nozzles 44 in each group, a rotary fixing piece 48 is arranged in the middle of the tar particle solidification chamber 57, and a spiral gas conveying component 46 is rotatably connected below the rotary fixing piece 48.

Further, the gas delivery subassembly 46 includes that the a week outside has set firmly the flight 47, it runs through tar granule and solidifies chamber 57 up end to rotate the stationary blade 48, oil granule solidifies chamber 57 up end and rotates stationary blade 48 fixedly connected with and rotates connection piece 49, it is equipped with hold-in range 51 to rotate the connection piece 49, the hold-in range 51 other end is connected with the output transmission of a motor 52, it is equipped with catalyst feed inlet 50 to rotate stationary blade 48 and tar granule and solidify chamber 57 up end space position, catalyst feed inlet 50 is through running through the catalyst pipeline 39 who rotates connection piece 49 and catalyst storage chamber 8 links to each other.

Further, the tar processing chamber 58 and the tar particle coagulation chamber 57 are connected by a tar collecting plate 45 fixedly arranged between the two, two ends of the tar collecting plate 45 are arc-shaped, the middle part is horizontally designed, tar seepage ports 43 are respectively arranged on two arc-shaped end surfaces of the tar collecting plate 45, a thermal insulation outer cover 40 is arranged at the tight connection part of the tar processing chamber 58 and the tar seepage ports 43, a rotatable tar guiding rod 41 is arranged in the thermal insulation outer cover 40, the tar guiding rod 41 is rotationally connected with the side wall of the tar processing chamber 58, stirring rods 42 are uniformly distributed on the tar guiding rod 41, two high-temperature heating rods 35 are arranged at the bottom of the tar processing chamber 58, the high-temperature heating rods 35 work through a heater arranged above the processing bottom plate 1, combustible gas in the tar particle coagulation chamber 57 is introduced into the second pumping pump 11 through a combustible gas second conveying pipeline 15, gas generated after tar processing in the tar processing chamber 58 is introduced into the second pumping pump 11 through a tar generated gas conveying pipeline 16, the second pumping pump 11 mixes the combustible gas and the gas generated after tar treatment and introduces the mixture into the gas power generation mechanism 14 for power generation, and the fuel storage cavity 12 sends the fuel to the gas power generation mechanism 14 through the fuel conveying pipeline 13 for biomass gasification power generation.

The working principle of the invention is as follows:

firstly, an implementer adds biomass raw materials into the device through a feeding chute 2 fixedly installed above one side of a processing bottom plate 1, a high-temperature-resistant conveying mechanism 29 is fixedly arranged inside the processing bottom plate 1, the conveying mechanism 29 conveys the biomass raw materials to a position below a raw material processing cavity 3, two raw material anti-falling guard plates 54 are respectively arranged on two sides of the conveying mechanism 29 and can prevent the raw materials from splashing in the conveying process, a trigger block 26 is fixedly arranged on one raw material anti-falling guard plate, two cavities 28 are arranged at two radial ends of the raw material processing cavity 3 in the inner part of a first fixing plate 10, two meshed gears 25 are fixedly arranged in each cavity 28, eight contact blocks 27 which are contacted with the trigger block 26 are uniformly arranged on the outer circle of each gear 25 in the radial direction, the two gears 25 are driven by the trigger block 26 to be meshed and rotate on the conveying mechanism 29, two sealing plates 55 which can slide up and down are arranged on one side of the two cavities 28 close to the raw material processing cavity 3, a connecting and fixing part 24 is fixedly arranged between the two closing plates 55, the two closing plates 55 are connected through the connecting and fixing part 24, and the two closing plates 55 descend under the meshing transmission of the gear 25 to form a closed space with the conveying mechanism 29 and the raw material processing cavity 3 for reacting the biomass raw materials.

When the biomass raw material completely reacts, seven atomizing nozzles 17 are uniformly arranged above the raw material anti-falling protective plate 54 and far away from the raw material processing cavity 3 inside the processing bottom plate 1, the seven atomizing nozzles 17 are connected and fixedly arranged in the water conveying pipeline 33 inside the processing bottom plate 1 above the seven atomizing nozzles 17, the other end of the water conveying pipeline 33 is connected into the water tank 36, tar particles of dust in reaction slag are solidified by water supplied by the water tank and sprayed by the atomizing nozzles, a drawable slag collecting component 56 is arranged below the conveying mechanism 29 and on the processing bottom plate 1, an arc-shaped slag splash-proof protective plate 32 is arranged on one side of the slag collecting component 56 close to the circular end face of the conveying mechanism 29, another arc-shaped tar scraper 31 is arranged on the other side of the slag collecting component 56, the reaction slag and tar are collected by the slag collecting component 56 and the arc-shaped tar scraper 31, and a slag collecting component position is fixedly arranged inside the processing bottom plate 1 on the horizontal direction of one side of the slag collecting component 56 provided with the arc-shaped scraper 31 A fixed stop 30 is provided, the fixed stop 30 fixing the operating position of the debris collection assembly 56.

After the biomass raw material completely reacts in the raw material processing chamber 3, two layers of filtering mechanisms are fixedly arranged above the raw material processing chamber 3, namely a first filtering plate 22 positioned below and a second filtering plate 21 positioned above the first filtering plate 22, one end of a second pumping and pressing pump 11 is respectively provided with a combustible gas second conveying pipeline 15 connected to the combustible gas processing mechanism 20 and a tar generated gas conveying pipeline 16, when the second pumping and pressing pump 11 pumps the combustible gas generated after the reaction into the combustible gas processing mechanism 20, small particle dust mixed in the gas is filtered through the two layers of filtering of the first filtering plate 22 and the second filtering plate 21, a tar particle solidification chamber 57 is arranged inside the combustible gas processing mechanism 20, a tar processing chamber 58 is arranged below the tar particle solidification chamber 57, two groups of catalyst spray heads 44 are respectively arranged at two ends in the tar particle solidification chamber 57, and four catalyst spray heads 44 are arranged in each group, and the sprayed liquid catalyst can cool the combustible gas, the temperature is reduced to gas tar particles to be condensed into liquid tar under the combined action of the catalyst, a rotary fixing piece 48 is arranged at the middle position of a tar particle solidification cavity 57, a spiral gas conveying assembly 46 is rotatably connected below the rotary fixing piece 48, a spiral sheet 47 is fixedly arranged on the outer side of the circumference of the gas conveying assembly 46, the spiral piece 47 will generate gas to further cool the combustible gas when rotating, and at the same time, the combustible gas can be continuously stirred, so that the gas tar particles in the combustible gas are more fully condensed, a catalyst feeding port 50 is arranged at the gap position of the upper end surfaces of the rotary fixing piece 48 and the tar particle coagulation cavity 57, the catalyst feeding port 50 is connected with the catalyst storage cavity 8 through a catalyst conveying pipeline 39 penetrating through the rotary connecting piece 49, the catalyst feeding port 50 leads the catalyst into the gas conveying assembly 46, the liquid catalyst cleans the gas delivery assembly 46 of condensed tar under the action of the rotating centrifuge.

After the liquid tar is flowed into the tar processing cavity 58 through the tight connection part of the tar processing cavity 58 and the tar seepage port 43, the thermal insulation outer cover 40 is arranged in the thermal insulation outer cover 40, the thermal insulation outer cover 40 can prevent the high temperature in the tar processing cavity 58 from being transferred into the combustible gas processing mechanism 20, the rotatable tar guiding rod 41 is arranged in the thermal insulation outer cover 40, stirring rods 42 are uniformly distributed on the tar guiding rod 41, two high-temperature heating rods 35 are arranged at the bottom of the tar processing cavity 58, the high-temperature heating rods 35 work through heaters arranged above the processing bottom plate 1, the liquid tar can be subjected to high-temperature cracking by the high-temperature heating rods 35 to generate combustible gas, the combustible gas in the tar particle solidification cavity 57 is introduced into the second pumping pump 11 through the combustible gas second conveying pipeline 15, the generated gas after the tar processing in the tar processing cavity 58 is introduced into the second pumping pump 11 through the tar generated gas conveying pipeline 16, and the combustible gas generated after the tar processing are mixed and introduced into the gas power generation mechanism 14 for generating power generation through the second pumping pump 11 And the fuel storage cavity 12 sends the fuel to the fuel gas power generation mechanism 14 through the fuel conveying pipeline 13 to complete biomass gasification power generation.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. A system for biomass gasification power generation, comprising a processing floor (1), characterized in that: a biomass raw material feeding groove (2) is fixedly installed above one side of the processing bottom plate (1), a first fixing plate (10) is fixedly arranged above the processing floor (1) and close to the raw material feeding groove (2), a raw material processing cavity (3) is fixedly arranged above the first fixing plate (10), a combustible gas first conveying pipeline (4) is arranged above the raw material processing cavity (3), a pumping pump (6) is arranged at the other end of the first conveying pipeline (4), a combustible gas processing mechanism (20) is arranged below the pumping pump (6) and on the processing bottom plate (1), a water tank (36) is arranged on one side, far away from the raw material feeding groove (2), above the processing bottom plate (1), a catalyst storage cavity (8) is fixedly arranged above the water tank (36), and a second pumping pump (11) is fixedly arranged above the processing bottom plate (1) and far away from the combustible gas processing mechanism (20), two pipeline interfaces at one end of the second pumping pump (11) are respectively connected into the combustible gas processing mechanism (20), a fuel gas power generation mechanism (14) is arranged at the other end of the second pumping pump, and a power generation mechanism fuel storage cavity (12) is fixedly arranged above the processing bottom plate (1) and close to the first fixing plate (10) and the combustible gas power generation mechanism (14).

2. The system for biomass gasification power generation according to claim 1, wherein: the inside of handling bottom plate (1) sets firmly high temperature resistance conveying mechanism (29), the both sides of conveying mechanism (29) are equipped with two raw materials respectively and prevent falling backplate (54), one of them the raw materials prevents falling and has set firmly trigger block (26) on the backplate, the radial both ends of the interior ring raw materials processing chamber (3) of first fixed plate (10) are equipped with two cavities (28), set firmly two engaged with gear (25) in every cavity (28), excircle a week of every gear (25) evenly be equipped with eight in the radial direction with trigger block (26) the contact piece (27) that contact.

3. A system for biomass gasification power generation according to claim 2, wherein: two closing plates (55) capable of sliding up and down are arranged on one side, close to the raw material processing cavity (3), of the two cavities (28), a connecting fixing piece (24) is fixedly arranged between the two closing plates (55), seven atomizing spray heads (17) are uniformly arranged in the processing bottom plate (1) above the raw material anti-falling protection plate (54) and far away from the raw material processing cavity (3), the seven atomizing spray heads (17) are connected into a water conveying pipeline (33) fixedly arranged above the seven atomizing spray heads in the processing bottom plate (1), the other end of the water conveying pipeline (33) is connected into the water tank (36), and a drawable slag collecting assembly (56) is arranged below the conveying mechanism (29) and on the processing bottom plate (1).

4. A system for biomass gasification power generation according to claim 3, wherein: the disintegrating slag collecting assembly (56) is including being close to arc disintegrating slag splashproof backplate (32) that one side of conveying mechanism (29) circular terminal surface was equipped with, the side of arc disintegrating slag splashproof backplate (32) still is equipped with arc tar scraper blade (31), one side that arc disintegrating slag splashproof backplate (32) were kept away from in arc tar scraper blade (31) is equipped with fixed dog (30), fixed dog (30) rotate spacingly to arc tar scraper blade 31.

5. The system for biomass gasification power generation according to claim 1, wherein: two layers of filtering mechanisms are fixedly arranged above the raw material processing chamber (3), namely a first filtering plate (22) positioned below and a second filtering plate (21) positioned above the first filtering plate, one end of the second pumping pump (11) is respectively provided with a combustible gas second delivery pipeline (15) and a tar generated gas delivery pipeline (16) which are connected into the combustible gas processing mechanism (20), a tar particle coagulation cavity (57) is arranged in the combustible gas treatment mechanism (20), a tar processing cavity (58) is arranged below the tar particle solidifying cavity (57), two groups of four catalyst spray heads (44) are respectively arranged at two ends in the tar particle solidification cavity (57), a rotary fixing piece (48) is arranged in the middle of the tar particle coagulation cavity (57), a spiral gas delivery assembly (46) is rotatably connected below the rotary fixing piece (48).

6. The system for biomass gasification power generation according to claim 1, wherein: gas delivery subassembly (46) include the a week outside and set firmly flight (47), it runs through to rotate stationary blade (48) tar granule solidifies chamber (57) up end, oil granule solidifies chamber (57) up end with rotate stationary blade (48) fixedly connected with and rotate connection piece (49), hold-in range (51) are equipped with on rotating connection piece (49), the hold-in range (51) other end is connected with the output transmission of a motor (52), rotate stationary blade (48) with tar granule solidifies chamber (57) up end space position and is equipped with catalyst feed inlet (50), catalyst feed inlet (50) are through running through catalyst pipeline (39) that rotate connection piece (49) with catalyst storage chamber (8) link to each other.

7. The system for biomass gasification power generation according to claim 4, wherein: the tar processing cavity (58) is connected with the tar collecting plate (45) between the tar particle solidifying cavity (57) through fixedly arranging the tar collecting plate (45), the two ends of the tar collecting plate (45) are arc-shaped, the middle part of the tar collecting plate is horizontally designed, tar seepage ports (43) are respectively arranged on the two arc-shaped end surfaces of the tar collecting plate (45), a temperature insulating outer cover (40) is arranged at the tight connection part of the tar seepage ports (43) in the tar processing cavity (58), a rotatable tar guiding rod (41) is arranged in the temperature insulating outer cover (40), the tar guiding rod (41) is rotationally connected with the side wall of the tar processing cavity (58), stirring rods (42) are uniformly distributed on the tar guiding rod (41), two high-temperature heating rods (35) are arranged at the bottom part of the tar processing cavity (58), and the high-temperature heating rods (35) are operated through a heater arranged above the processing bottom plate (1), combustible gas lets in through combustible gas second pipeline (15) in tar granule coagulation chamber (57) in second pumping pump (11), tar is handled in tar processing chamber (58) and is produced gas and let in through tar production gas pipeline (16) in second pumping pump (11), second pumping pump (11) are produced gas mixture and are let in gas power generation mechanism (14) and generate electricity after combustible gas and tar are handled, fuel storage chamber (12) are sent fuel to gas power generation mechanism (14) through fuel pipeline (13) and are carried out biomass gasification electricity generation.