CN211952799U - Movable biomass power generation integrated device - Google Patents

Abstract

The utility model discloses a portable biomass power generation integrated device, including integration power generation facility, PCL controller and air-blast device, wherein, integration power generation facility mainly includes dry reducing mechanism of living beings, loading attachment, burning, electricity generation, accumulate device to and processing apparatus is collected to the lime-ash, and wherein integration power generation facility bottom welding is on unable adjustment base, and unable adjustment base has the wheel of fixing, realizes removing. This portable biomass power generation integrated device can be regularly quantitative carry out the supply of raw materials, has overcome the burning incoherence problem that biomass fuel density is low to bring, and the combustion chamber sets up the supersound vibrations disc simultaneously, makes the fuel be half suspension state, improves its heat value of combustion, and wherein each device is compact to be related, is favorable to improving production efficiency, is convenient for to the processing of waste gas, waste residue, reduces the pollution discharge.

Description

Movable biomass power generation integrated device

Technical Field

The utility model relates to a power generation field specifically is a portable biomass power generation integrated device.

Background

The current energy situation of China is not optimistic, the non-renewable resources are reduced day by day, and the energy application is tense, so the development work of novel renewable energy becomes a high concern item in the field of energy application. The biomass power generation technology is a technical environment-friendly power generation technology concept which is made up by following the requirements of the times, the biomass material is used for generating power, the economic benefit of an electric power growth enterprise can be improved, the production cost is reduced, the rural industrial structure can be deepened, more income ways are brought to farmers, new employment posts are provided, the recycling of waste is realized, the environmental pollution is effectively avoided, the frequency of possible fire hazard caused by unmanned management of the waste is reduced, and the biomass power generation technology has important practical significance for relieving the current situation of the environmental pollution in China and improving the social and economic strength in China.

Patent CN107699474A describes a biomass power plant, which is characterized in that biomass is fermented to produce biogas by means of gasification, and the biogas is used for power generation. The solar biogas digester fully utilizes solar energy and a convex lens to maintain the temperature in the biogas digester, so that stable operation can be maintained in winter, and then a fan-shaped suction device is utilized to collect the generated biogas; patent CN108048134A describes a biomass gasification power generation device, which uses a series of devices, such as a spiral feeder, a biomass gasification furnace, a cyclone dust collector, and a filter, connected in sequence to make biomass into gas and then burn, and the steam generated by burning enters a gas generator; patent CN109973241A describes a biomass power generation device and method, in which a drying and extruding device is arranged on a conveying device to ensure stable combustion after extrusion molding of raw materials, and a stirling generator is arranged at the same time. However, the problems that the combustion is interrupted easily due to high water content and low heat value of the biomass fuel, a large amount of air needs to be supplemented when the combustion speed is high, and the like are still one of the problems faced by the biomass combustion.

SUMMERY OF THE UTILITY MODEL

Based on the weak point among the prior art mentioned among the above-mentioned background art, for this reason the utility model provides a portable biomass power generation integrated device.

The utility model discloses an adopt following technical scheme to overcome above technical problem, specifically do:

a movable biomass power generation integrated device comprises integrated power generation equipment, a PLC (programmable logic controller) and a blower device, wherein the blower device, the PLC and the integrated power generation equipment are all arranged on a fixed chassis with fixable wheels at the lower part, and the integrated power generation equipment comprises a feeding device, a biomass drying and crushing device, a combustion device, a power generation device, a power storage device and an ash collecting and processing device which are arranged in the integrated power generation equipment; the drying and crushing device comprises a drying cylinder arranged on one side of the upper portion of the integrated power generation equipment, a crushing cylinder fixed in the integrated power generation equipment and arranged in a staggered mode with the drying cylinder, and a conveying cylinder fixed in the integrated power generation equipment and arranged in a staggered mode with the crushing cylinder, and the feeding device comprises a conveying belt penetrating through the side edge of the drying cylinder.

As a further aspect of the present invention: the drying cylinder is internally provided with a horizontal first fuel conveying belt, a first mechanical gripper is movably connected above the first fuel conveying belt, and the first mechanical gripper is linearly connected with the first mechanical gripper and the upper inner wall of the drying cylinder through a first fixed chain.

As a further aspect of the present invention: the drying device is characterized in that a hot air component is fixed on the outer wall of the upper portion of the drying cylinder and comprises a small motor, a heating rod and a heater, wherein the small motor is mounted on the outer wall of the drying cylinder, the heating rod is movably arranged on the outer wall of the drying cylinder and connected with the output end of the small motor, the heater is covered outside the heating rod and is connected with the outer wall of the drying cylinder, and a penetrating needle-shaped hot air hole is formed between the heater and the side wall of the drying cylinder.

As a further aspect of the present invention: a first conveying port is formed in one end, close to the conveyor belt, of the crushing cylinder and one end, far away from the conveyor belt, of the drying cylinder in a penetrating and communicating mode, hobbing cutters are arranged in the crushing cylinder in a rotating mode, two hobbing cutters form one group, three groups of hobbing cutters are arranged in the crushing cylinder, and a bearing plate which is fixedly inclined downwards with the crushing cylinder is arranged between every two adjacent groups of hobbing cutters; and a second conveying opening which is communicated in a penetrating manner is arranged between one end, far away from the conveyor belt, of the crushing cylinder and one end, close to the conveyor belt, of the conveying cylinder.

As a further aspect of the present invention: a fuel concentration box fixed in the conveying cylinder is arranged below the second conveying opening, a second mechanical gripper is movably arranged above the inner wall of the conveying cylinder, and the second mechanical gripper is linearly connected with the second mechanical gripper and the upper inner wall of the conveying cylinder through a second fixed chain; a second fuel conveying belt which is horizontally arranged in the conveying cylinder is arranged below the second mechanical gripper, and a plurality of movable baffles are arranged on the second fuel conveying belt at equal intervals; and a third conveying opening is formed below one end, far away from the conveying belt, of the conveying cylinder.

As a further aspect of the present invention: a feeding machine is arranged below the third conveying port, and a plurality of material conveying boxes are arranged on the circumference of the feeding machine at equal intervals; the feeding machine comprises two feeding machine fixing columns fixed in the integrated power generation equipment, a mechanical compass rotatably mounted at the tops of the two feeding machine fixing columns, and a mechanical compass fixing string fixed on the circumference of the mechanical compass, wherein the material conveying box is mounted on the mechanical compass fixing string; the mechanical compass is in signal connection with the first mechanical gripper and the second mechanical gripper through a PLC controller.

As a further aspect of the present invention: the combustion device comprises a combustion chamber arranged in the integrated power generation equipment and an ultrasonic vibration disc arranged at the bottom of the combustion chamber, wherein a feed inlet corresponding to the feeding machine is formed in the upper part of the combustion chamber; the air blowing device comprises a plurality of air blowers, a plurality of air supply holes communicated with the air inlets at the bottom of the combustion chamber are formed in the side wall of the combustion chamber, and the air inlets are communicated with the output ports of the air blowers through air supply pipes.

As a further aspect of the present invention: the power generation device comprises a power generation box which is arranged at the upper part of the combustion chamber and fixed with the upper wall of the integrated power generation equipment, and the power storage device is a power storage box which is fixed on the outer wall of the integrated power generation equipment and electrically connected with the power generation box; the upper part of the combustion chamber is provided with a through hole communicated with the power generation box, and a steam collecting filter hopper is arranged at the through hole.

As a further aspect of the present invention: the ash collecting and processing device comprises an ash conveying assembly and a compacting assembly; the ash conveying component comprises a slag conveying pipe arranged at the bottom of the integrated power generation equipment, a spiral slag conveying disc rotatably installed in the slag conveying pipe and an ash collecting chamber communicated with the slag conveying pipe, wherein the bottom of the combustion chamber is inclined towards one end of the slag conveying pipe, and an ash conveying port communicated with the output end of the slag conveying pipe is arranged at the bottom of the ash collecting chamber.

As a further aspect of the present invention: the compaction assembly comprises a plurality of ash collecting boxes arranged in the ash collecting chamber, an elliptical fixed chain movably connected to the upper wall of the ash collecting chamber is arranged at the upper part of each ash collecting box, an ash pressing disc is arranged right above each ash collecting box, the ash pressing discs are arranged below telescopic rods, and the upper parts of the telescopic rods are arranged on the elliptical fixed chains through pulleys; the top of the ash collecting chamber is provided with a mechanical gear fixing seat, the mechanical gear fixing seat is connected with an oval fixing chain through a mechanical gear, a telescopic rod is in signal connection with the PLC, and an ash conveying belt is arranged at the bottom of one side of the ash collecting chamber, which is opposite to the ash conveying port, in a through mode.

After the structure more than adopting, the utility model discloses compare in prior art, possess following advantage: the utility model discloses can be regularly quantitative carry out the supply of raw materials, overcome the burning that biomass fuel density low brought and do not link up the problem, the combustion chamber sets up the supersound vibrations disc simultaneously, makes the fuel be half suspended state, improves its heat value of combustion, and wherein each device is compact and is linked, is favorable to improving production efficiency, is convenient for to the processing of waste gas, waste residue, and pollution abatement discharges.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a mobile biomass power generation integrated device;

FIG. 2 is a schematic cross-sectional view of an integrated power generation facility in a mobile biomass power generation integrated unit;

FIG. 3 is a schematic cross-sectional view of a drying and pulverizing apparatus in a mobile biomass power generation integrated apparatus;

FIG. 4 is a schematic cross-sectional view of a mobile biomass power generation integrated apparatus and a method loading apparatus;

FIG. 5 is a detailed schematic diagram of a mobile biomass power generation integrated device and method ash collecting chamber.

In the figure: 1. a fixed base; 2. the wheel can be fixed; 3, a PLC controller; 4. an integrated power generation device; 5. a blower; 6, supplying a gas pipe; 7. a conveyor belt; 8. an ash conveyor belt; 9. drying the cylinder; 10. a grinding cylinder; 11. a delivery cylinder; 12. fixing a column; 13. a feeding machine; 14. a material transporting box; 15. an electricity storage box; 16. a power generation box; 17. a steam collecting filter hopper; 18. a feed inlet; 19. a combustion chamber; 20. an air supply hole; 21. ultrasonically vibrating the disc; 22. an air inlet; 23. a slag conveying pipe; 24. a spiral slag conveying disc; 25. a slag collection chamber; 26. a heater; 27. a heating rod; 28. a small-sized motor; 29. a first fixed chain; 30. a mechanical gripper; a first conveyor belt; 32. a first delivery port; 33. hobbing cutters; 34. a bearing plate; 35. a second delivery port; 36. a fuel collection tank; number two anchor chains; 38. a second mechanical gripper; 39. a second conveying belt; 40. a movable flapper; 41. a third delivery port; 42. a mechanical compass; 43. a fixing column of the feeding machine; 44. a mechanical compass fixes a string; 45. an ash conveying port; 46. an ash collecting box; 47. the ash pressing disc; 48. a telescopic rod; 49. a pulley; 50. an elliptical fixed chain; 51. a mechanical gear fixing seat; 52. a mechanical gear; 53. and (4) needle-shaped hot air holes.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

In addition, an element of the present invention may be said to be "secured to" or "disposed on" another element, either directly on the other element or with intervening elements present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Referring to fig. 1, in an embodiment of the present invention, a mobile integrated biomass power generation device includes an integrated power generation device 4, a PLC controller 3 and a blower device, the PLC controller 3 and the integrated power generation device 4 are all installed on a fixed chassis 1 whose lower portion is provided with a fixable wheel 2, wherein the integrated power generation device 4 includes a feeding device, a biomass drying and crushing device, a combustion device, a power generation device, a power storage device and an ash collecting and processing device which are arranged in the integrated power generation device 4.

Further, referring to fig. 2, the drying and pulverizing device includes a drying cylinder 9 disposed on one side of the upper portion of the integrated power generation equipment 4, a pulverizing cylinder 10 fixed in the integrated power generation equipment 4 and disposed in a staggered manner with respect to the drying cylinder 9, and a conveying cylinder 11 fixed in the integrated power generation equipment 4 and disposed in a staggered manner with respect to the pulverizing cylinder 10, the feeding device includes a conveyor belt 7 penetrating through the side of the drying cylinder 9, and the raw biomass fuel is conveyed into the drying cylinder 9 in the integrated power generation equipment 4 through the conveyor belt 7; the drying cylinder 9 has a double-layer inner cavity, and the drying cylinder 9, the crushing cylinder 10, and the conveying cylinder 11 are all fixed on the integrated power generation equipment 4 through fixing columns 12.

Referring to fig. 3, a horizontal first fuel conveying belt 31 is arranged in the drying cylinder 9, a first mechanical gripper 30 is movably connected above the first fuel conveying belt 31, the first mechanical gripper 30 is linearly connected with the first mechanical gripper 30 and the upper inner wall of the drying cylinder 9 through a first fixed chain 29, biomass fuel conveyed to the drying cylinder 9 directly falls on the first fuel conveying belt 31, and the first mechanical gripper 30 connected with the linear first fixed chain 29 can uniformly spread the biomass fuel;

a hot air assembly is fixed on the outer wall of the upper part of the drying cylinder 9, and comprises a small motor 28 arranged on the outer wall of the drying cylinder 9, a heating rod 27 movably arranged on the outer wall of the drying cylinder 9 and connected with the output end of the small motor 28, and a hot air device 26 covered outside the heating rod 27 and connected with the outer wall of the drying cylinder 9, wherein a penetrating needle-shaped hot air hole 53 is formed between the hot air device 26 and the side wall of the drying cylinder 9;

under the action of a small motor 28, the heating rod 27 is heated, the hot air device 26 works, and heated hot air is injected into the inner cavity of the drying cylinder 9 through the needle-shaped hot air holes 53 to dry the fuel biomass.

The grinding cylinder 10 is close to one end of the conveyor belt 7 and one end of the drying cylinder 9 far away from the conveyor belt 7 are provided with a first conveying port 32 in a penetrating and communicating mode, the grinding cylinder 10 rotates internally and is provided with three hobbing cutters 33, wherein the two hobbing cutters 33 are in a group, three groups of hobbing cutters 33 are arranged in the grinding cylinder 10, and a receiving plate 34 which is inclined downwards and fixed to the grinding cylinder 10 is arranged between every two adjacent groups of hobbing cutters 33.

Smash drum 10 and keep away from the one end of conveyer belt 7 is close to with transport drum 11 be provided with the second delivery port 35 that runs through the intercommunication between the one end of conveyer belt 7, under fuel conveyer belt 31's effect, fuel is in first delivery port 32 fortune to smash drum 10, directly gets into first group hobbing cutter 33 and smashes, the fuel after preliminary crushing gets into second group hobbing cutter 33 under the effect of adapter plate 34, and in the same way, after second group hobbing cutter 33 smashes, fuel gets into third group hobbing cutter 33 through another adapter plate 34, and the fuel after three group hobbing cutter 33 smashes gets into in carrying drum 11 through second delivery port 35.

A fuel concentration box 36 fixed in the conveying cylinder 11 is arranged below the second conveying opening 35, a second mechanical gripper 38 is movably arranged above the inner wall of the conveying cylinder 11, and the second mechanical gripper 38 is linearly connected with the second mechanical gripper 38 and the upper inner wall of the conveying cylinder 11 through a second fixed chain 37; a second fuel conveying belt 39 which is horizontally arranged in the conveying cylinder 11 is arranged below the second mechanical gripper 38, and a plurality of movable baffles 40 are equidistantly arranged on the second fuel conveying belt 39; a third conveying opening 41 is formed below one end, far away from the conveyor belt 7, of the conveying cylinder 11;

the biomass fuel is captured in the space between the movable flaps 40 of the second fuel conveyor 39 by the second mechanical gripper 38, and the fuel is discharged through the third delivery port 41 by the second fuel conveyor 39.

A feeding machine 13 is arranged below the third conveying port 41, and a plurality of material conveying boxes 14 are arranged on the circumference of the feeding machine 13 at equal intervals;

in detail, referring to fig. 4, the feeder 13 includes two feeder fixing posts 43 fixed in the integrated power generation equipment 4, a mechanical compass 42 rotatably mounted on top of the two feeder fixing posts 43, and a mechanical compass fixing string 44 fixed on the circumference of the mechanical compass 42, wherein the material transporting box 14 is mounted on the mechanical compass fixing string 44;

the mechanical compass 42 is in signal connection with the first mechanical hand grip 30 and the second mechanical hand grip 38 to the PLC controller 3.

The fuel enters the material transporting box 14 on the feeding machine 13 through the third delivery port 41, the fuel quantity between the movable baffles 40 is controlled by controlling the action of the second mechanical hand grip 38, the quantitative determination of the fuel in the material transporting box 14 is realized, the PLC 3 is used for controlling, and the feeding machine 13 operates under the action of the mechanical compass 42.

The combustion device comprises a combustion chamber 19 arranged in the integrated power generation equipment 4 and an ultrasonic vibration disc 21 arranged at the bottom of the combustion chamber 19, wherein a feed port 18 corresponding to the feeding machine 13 is formed in the upper part of the combustion chamber 19, the fuel on the material conveying box 14 pours the crushed biomass fuel into the combustion chamber 19 through the feed port 18, and the biomass fuel is in a semi-suspension state after entering the combustion chamber under the action of the ultrasonic vibration disc 21;

still further, the air blowing device comprises a plurality of air blowers 5, a plurality of air supply holes 20 communicated with air inlets 22 at the bottom of the combustion chamber 19 are formed in the side wall of the combustion chamber 19, the air inlets 22 are communicated with the output ports of the air blowers 5 through air supply pipes 6, after fuel enters the combustion chamber 19, the ultrasonic vibration disc 21 is opened, the air blowers 5 are simultaneously started in a time-sharing and sectional mode, low-temperature steam enters the air inlets 22 through the air supply pipes 6, the air supply holes 20 supply air into the combustion chamber 19, and the combusted biomass fuel generates high-temperature hot steam.

The power generation device comprises a power generation box 16 which is arranged at the upper part of the combustion chamber 19 and fixed with the upper wall of the integrated power generation equipment 4, and the power storage device is a power storage box 15 which is fixed on the outer wall of the integrated power generation equipment 4 and electrically connected with the power generation box 16;

it should be noted that a through opening communicated with the power generation box 16 is arranged at the upper part of the combustion chamber 19, a steam collection filter 17 is installed at the through opening, the steam collection filter 17 is used for intercepting part of fly ash generated by the combustion of the biomass fuel, the steam enters the power generation box 16 for power generation, and the electric energy is stored in the power storage box 15 after the power generation.

Referring to fig. 5, the ash collection and handling apparatus includes an ash transfer assembly and a compacting assembly;

the ash conveying component comprises a slag conveying pipe 23 arranged at the bottom of the integrated power generation equipment 4, a spiral slag conveying disc 24 rotatably installed in the slag conveying pipe 23, and an ash collecting chamber 25 communicated with the slag conveying pipe 23, wherein the bottom of the combustion chamber 19 is inclined towards one end of the slag conveying pipe 23, and an ash conveying port 45 communicated with the output end of the slag conveying pipe 23 is arranged at the bottom of the ash collecting chamber 25;

the burnt ash is centralized in the slag conveying pipe 23 under the action of the bottom end of the inclined combustion chamber 19 and is spirally conveyed to the ash collecting chamber 25 through an ash conveying port 45 under the action of a spiral slag conveying disc 24;

the compaction assembly comprises a plurality of ash collecting boxes 46 arranged in the ash collecting chamber 25, an elliptical fixed chain 50 movably connected with the upper wall of the ash collecting chamber 25 is arranged at the upper part of each ash collecting box 46, an ash pressing disc 47 is arranged right above each ash collecting box 46, the ash pressing disc 47 is arranged below a telescopic rod 48, and the upper part of the telescopic rod 48 is arranged on the elliptical fixed chain 50 through a pulley 49;

furthermore, a mechanical gear fixing seat 51 is installed on the top of the ash collecting chamber 25, the mechanical gear fixing seat 51 is connected with an elliptical fixing chain 50 through a mechanical gear 52, an extensible rod 48 is in signal connection with the PLC 3, and an ash conveying belt 8 is installed at the bottom of one side of the ash collecting chamber 25 opposite to the ash conveying port 45 in a penetrating way;

through spiral slag conveying disc 24 directly with the lime-ash carry to the lime-ash box 46 of collecting, regularly pass through PLC controller 3, but control telescopic link 48 drives the lime-ash and presses disc 47 and press the lime-ash in the lime-ash box 46, make the lime-ash durable stable, under mechanical gear's 52 drive, the lime-ash of filling up is collected box 46 below chassis and is opened, will stabilize fashioned lime-ash and transport to the lime-ash conveyer belt 8 on, carry out lime-ash collection chamber 25, concentrate recovery processing can.

The foregoing is illustrative of the preferred embodiments of the present invention only, and is not to be construed as limiting the claims. The present invention is not limited to the above embodiments, and the specific structure thereof is allowed to be changed. However, all changes which come within the scope of the independent claims of the invention are to be embraced therein.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Claims (10)

1. A movable biomass power generation integrated device is characterized by comprising an integrated power generation device (4), a PLC (programmable logic controller) and a blower device, wherein the blower device, the PLC (3) and the integrated power generation device (4) are all arranged on a fixed chassis (1) with the lower part provided with a fixable wheel (2), and the integrated power generation device (4) comprises a feeding device, a biomass drying and crushing device, a combustion device, a power generation device, a power storage device and an ash collecting and processing device which are arranged in the integrated power generation device (4); the drying and crushing device comprises a drying cylinder (9) arranged on one side of the upper portion of the integrated power generation equipment (4), a crushing cylinder (10) fixed in the integrated power generation equipment (4) and arranged in a staggered mode with the drying cylinder (9), and a conveying cylinder (11) fixed in the integrated power generation equipment (4) and arranged in a staggered mode with the crushing cylinder (10), and the feeding device comprises a conveying belt (7) arranged on the side edge of the drying cylinder (9) in a penetrating mode.

2. The integrated mobile biomass power generation device as claimed in claim 1, wherein a horizontal first fuel conveying belt (31) is arranged in the drying cylinder (9), a first mechanical gripper (30) is movably connected above the first fuel conveying belt (31), and the first mechanical gripper (30) is linearly connected with the first mechanical gripper (30) and the upper inner wall of the drying cylinder (9) through a first fixing chain (29).

3. The integrated mobile biomass power generation device according to claim 2, wherein a hot air assembly is fixed on the outer wall of the upper part of the drying cylinder (9), and comprises a small motor (28) installed on the outer wall of the drying cylinder (9), a heating rod (27) movably arranged on the outer wall of the drying cylinder (9) and connected with the output end of the small motor (28), and a heater (26) covered outside the heating rod (27) and connected with the outer wall of the drying cylinder (9), wherein a through needle-shaped hot air hole (53) is formed between the heater (26) and the side wall of the drying cylinder (9).

4. The integrated mobile biomass power generation device according to claim 2, wherein a first delivery port (32) is formed in the end, close to the conveyor belt (7), of the crushing cylinder (10) and the end, far away from the conveyor belt (7), of the drying cylinder (9) in a penetrating and communicating manner, and rolling cutters (33) are rotatably arranged in the crushing cylinder (10), wherein two rolling cutters (33) form one group, three groups of rolling cutters (33) are arranged in the crushing cylinder (10), and a downward inclined bearing plate (34) fixed with the crushing cylinder (10) is arranged between two adjacent groups of rolling cutters (33); a second conveying opening (35) which penetrates and is communicated is arranged between one end, far away from the conveyor belt (7), of the crushing cylinder (10) and one end, close to the conveyor belt (7), of the conveying cylinder (11).

5. The integrated mobile biomass power generation device according to claim 4, wherein a fuel concentration box (36) fixed in the conveying cylinder (11) is arranged below the second conveying port (35), a second mechanical gripper (38) is movably arranged above the inner wall of the conveying cylinder (11), and the second mechanical gripper (38) is linearly connected with the second mechanical gripper (38) and the upper inner wall of the conveying cylinder (11) through a second fixed chain (37); a second fuel conveying belt (39) which is installed in the conveying cylinder (11) and is horizontal is arranged below the second mechanical gripper (38), and a plurality of movable baffles (40) are arranged on the second fuel conveying belt (39) at equal intervals; and a third conveying opening (41) is formed below one end, far away from the conveyor belt (7), of the conveying cylinder (11).

6. The integrated mobile biomass power generation device according to claim 5, wherein a feeding machine (13) is arranged below the third delivery port (41), and a plurality of material conveying boxes (14) are arranged on the circumference of the feeding machine (13) at equal intervals; the feeding machine (13) comprises two feeding machine fixing columns (43) fixed in the integrated power generation equipment (4), a mechanical compass (42) rotatably mounted at the tops of the two feeding machine fixing columns (43), and a mechanical compass fixing string (44) fixed on the circumference of the mechanical compass (42), wherein the material conveying box (14) is mounted on the mechanical compass fixing string (44); the mechanical compass (42) is in signal connection with the first mechanical gripper (30) and the second mechanical gripper (38) to the PLC controller (3).

7. The integrated mobile biomass power generation device as claimed in claim 6, wherein the combustion device comprises a combustion chamber (19) arranged in the integrated power generation equipment (4) and an ultrasonic vibration disc (21) arranged at the bottom of the combustion chamber (19), wherein the upper part of the combustion chamber (19) is provided with a feed port (18) corresponding to the feeding machine (13); the air blowing device comprises a plurality of air blowers (5), a plurality of air supply holes (20) communicated with air inlets (22) at the bottoms of the combustion chambers (19) are formed in the side walls of the combustion chambers (19), and the air inlets (22) are communicated with output ports of the air blowers (5) through air supply pipes (6).

8. The integrated mobile biomass power generation device according to claim 7, characterized in that the power generation device comprises a power generation box (16) which is arranged at the upper part of the combustion chamber (19) and fixed with the upper wall of the integrated power generation equipment (4), and the power storage device is a power storage box (15) which is fixed on the outer wall of the integrated power generation equipment (4) and electrically connected with the power generation box (16); the upper part of the combustion chamber (19) is provided with a through hole communicated with the power generation box (16), and a steam collection filter hopper (17) is arranged at the through hole.

9. The integrated mobile biomass power generation device as claimed in claim 7, wherein the ash collection and processing device comprises an ash conveying assembly and a compacting assembly; the ash conveying component comprises a slag conveying pipe (23) arranged at the bottom of the integrated power generation equipment (4), a spiral slag conveying disc (24) rotatably installed in the slag conveying pipe (23) and an ash collecting chamber (25) communicated with the slag conveying pipe (23), wherein the bottom of the combustion chamber (19) is inclined to the inclined part at one end of the slag conveying pipe (23), and an ash conveying port (45) communicated with the output end of the slag conveying pipe (23) is formed in the bottom of the ash collecting chamber (25).

10. The integrated mobile biomass power generation device as claimed in claim 9, wherein the compacting assembly comprises a plurality of ash collecting boxes (46) arranged in the ash collecting chamber (25), the upper parts of the ash collecting boxes (46) are provided with elliptical fixed chains (50) movably connected to the upper wall of the ash collecting chamber (25), an ash pressing disc (47) is arranged right above each ash collecting box (46), the ash pressing disc (47) is arranged below the telescopic rods (48), and the upper parts of the telescopic rods (48) are arranged on the elliptical fixed chains (50) through pulleys (49); mechanical gear fixing base (51) are installed at the top of ash collecting chamber (25), oval fixed chain (50) are connected through mechanical gear (52) in mechanical gear fixing base (51), telescopic rod (48) signal connection PLC controller (3), it is relative in ash collecting chamber (25) one side bottom of ash delivery port (45) link up and install ash conveyer belt (8).

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