阅读说明：本技术 生物质颗粒燃烧炉 (Biomass particle combustion furnace ) 是由 王景春 于 2020-12-24 设计创作，主要内容包括：本发明涉及燃烧炉设备技术领域,更具体的说是生物质颗粒燃烧炉,具有能减少生物质颗粒掉渣的情况的优点,包括壳体组件、压缩组件、传动组件、进料组件、出料组件、驱动组件、载料组件和添料燃烧组件,所述压缩组件滑动连接在壳体组件上,传动组件转动连接在壳体组件上,压缩组件和传动组件啮合传动,进料组件滑动连接在壳体组件上,出料组件滑动连接在壳体组件的下端,驱动组件固定连接在壳体组件上,传动组件和驱动组件啮合传动,进料组件和出料组件均与驱动组件啮合传动,载料组件固定连接在壳体组件上,载料组件和驱动组件啮合传动,添料燃烧组件连接在壳体组件上。(The invention relates to the technical field of combustion furnace equipment, in particular to a biomass particle combustion furnace which has the advantage of reducing slag falling of biomass particles and comprises a shell assembly, a compression assembly, a transmission assembly, a feeding assembly, a discharging assembly, a driving assembly, a loading assembly and a charging combustion assembly, compression subassembly sliding connection is on housing assembly, drive assembly rotates to be connected on housing assembly, compression subassembly and drive assembly meshing transmission, feeding subassembly sliding connection is on housing assembly, ejection of compact subassembly sliding connection is at housing assembly's lower extreme, drive assembly fixed connection is on housing assembly, drive assembly and drive assembly meshing transmission, feeding subassembly and ejection of compact subassembly all mesh transmission with drive assembly, carry material subassembly fixed connection on housing assembly, carry material subassembly and drive assembly meshing transmission, add material burning subassembly and connect on housing assembly.)

1. Biomass particle fires burning furnace, including casing subassembly (1), compression subassembly (2), drive assembly (3), feeding subassembly (4), ejection of compact subassembly (5), drive assembly (6), carry material subassembly (7) and add material burning subassembly (8), its characterized in that: compression subassembly (2) sliding connection is on casing subassembly (1), drive assembly (3) rotate to be connected on casing subassembly (1), compression subassembly (2) and drive assembly (3) meshing transmission, feeding subassembly (4) sliding connection is on casing subassembly (1), ejection of compact subassembly (5) sliding connection is at the lower extreme of casing subassembly (1), drive assembly (6) fixed connection is on casing subassembly (1), drive assembly (3) and drive assembly (6) meshing transmission, feeding subassembly (4) and ejection of compact subassembly (5) all mesh transmission with drive assembly (6), carry material subassembly (7) fixed connection on casing subassembly (1), carry material subassembly (7) and drive assembly (6) meshing transmission, add material burning component (8) and connect on casing subassembly (1).

2. The biomass particle combustion furnace as set forth in claim 1, wherein: the shell assembly (1) comprises a combustion furnace (101), an ignition mechanism (102), a lower slideway (103), a feeding baffle plate (104), a forming barrel (105), an upper slideway (106) and a communicating pipe (107), wherein the ignition mechanism (102) is fixedly connected to the lower end of the combustion furnace (101), the lower slideway (103) is fixedly connected to the combustion furnace (101), the feeding baffle plate (104) is slidably connected to the lower slideway (103), the forming barrel (105) is fixedly connected to the lower slideway (103), the upper slideway (106) is fixedly connected to the upper end of the forming barrel (105), and the communicating pipe (107) is fixedly connected to the forming barrel (105).

3. The biomass particle combustion furnace as set forth in claim 2, wherein: compression component (2) are including contour plate (201), waist type threaded rod (202), screwed pipe gear (203), spring plate (204) and reset spring (205), contour plate (201) sliding connection is in shaping bucket (105), fixedly connected with waist type threaded rod (202) on contour plate (201), screwed pipe gear (203) rotate to be connected on shaping bucket (105), waist type threaded rod (202) and screwed pipe gear (203) pass through the screw drive, spring plate (204) rotate to be connected on screwed pipe gear (203), fixedly connected with reset spring (205) between the upper end of waist type threaded rod (202) and spring plate (204).

4. The biomass particle combustion furnace as set forth in claim 3, wherein: the transmission assembly (3) comprises a first half-tooth gear (301), an interval missing-tooth gear (302) and a transmission wheel (303), the first half-tooth gear (301) is rotatably connected to the forming barrel (105), the interval missing-tooth gear (302) and the transmission wheel (303) are fixedly connected to the first half-tooth gear (301), and the first half-tooth gear (301) and the threaded pipe gear (203) are in meshing transmission.

5. The biomass particle combustion furnace as set forth in claim 4, wherein: the feeding assembly (4) comprises a feeding fixing plate (401), a feeding spring (402), a feeding push plate (403) and a feeding rack (404), wherein the feeding fixing plate (401) is fixedly connected to the upper slideway (106), the feeding spring (402) is fixedly connected to the feeding fixing plate (401), the feeding push plate (403) is slidably connected to the upper slideway (106), the feeding push plate (403) is fixedly connected to the feeding spring (402), and the feeding rack (404) is fixedly connected to the feeding push plate (403).

6. The biomass particle combustion furnace as set forth in claim 5, wherein: ejection of compact subassembly (5) is including ejection of compact fixed plate (501), ejection of compact cutting board (502), ejection of compact rack (503), ejection of compact push pedal (504) and return piece (505), ejection of compact fixed plate (501) fixed connection is on glide slope (103), ejection of compact cutting board (502) sliding connection is on glide slope (103), fixedly connected with spring between ejection of compact fixed plate (501) and the ejection of compact cutting board (502), ejection of compact rack (503) fixed connection is on ejection of compact cutting board (502), ejection of compact push pedal (504) sliding connection is on ejection of compact cutting board (502), two return pieces of fixedly connected with (505) on ejection of compact push pedal (504).

7. The biomass particle combustion furnace as set forth in claim 6, wherein: the driving assembly (6) comprises a driving motor (601), worm gears (602), material conveying input teeth (603), symmetrical gears (604), rack gears (605), a material conveying mounting plate (606), transmission input teeth (607) and a transmission worm shaft (608), the driving motor (601) is fixedly connected to the lower slideway (103), two worm gears (602) are fixedly connected to an output shaft of the driving motor (601), the material conveying mounting plate (606) is fixedly connected to the forming barrel (105), the symmetrical gears (604) are rotatably connected to the material conveying mounting plate (606), the material conveying input teeth (603) are fixedly connected to the symmetrical gears (604), the symmetrical gears (604) are in meshing transmission with the worm gears (602) at the lower end, the upper end and the lower end of the material conveying mounting plate (606) are both rotatably connected with the rack gears (605), and the two rack gears (605) are both in meshing transmission with the symmetrical gears (604), the feeding rack (404) and the discharging rack (503) are respectively meshed with two rack gears (605) for transmission, a transmission worm shaft (608) is rotatably connected to the upper slideway (106), a transmission input tooth (607) is fixedly connected to the transmission worm shaft (608), the transmission input tooth (607) is meshed with the worm gear (602) at the upper end for transmission, and the transmission worm shaft (608) is meshed with the transmission wheel (303) for transmission.

8. The biomass particle combustion furnace as set forth in claim 7, wherein: the material loading assembly (7) comprises a material loading baffle (701), a rotating gear plate (702) and a material loading box (703), the material loading baffle (701) is fixedly connected to the upper slideway (106), the rotating gear plate (702) is rotatably connected to the material loading baffle (701), the material loading box (703) is fixedly connected to the upper slideway (106), and the rotating gear plate (702) and the material loading box (703) are rotatably connected.

9. The biomass particle combustion furnace as set forth in claim 8, wherein: the feeding combustion assembly (8) comprises a combustion rotating motor (801), a feeding cam (802), a feeding rotating wheel (803), a ventilation combustion plate (804) and an annular gear ring (805), wherein the combustion rotating motor (801) is fixedly connected to a lower slideway (103), the feeding cam (802) and the feeding rotating wheel (803) are both fixedly connected to an output shaft of the combustion rotating motor (801), the feeding cam (802) is in line contact with a feeding baffle (104), the ventilation combustion plate (804) is rotatably connected to the inside of a combustion furnace (101), the annular gear ring (805) is fixedly connected to the ventilation combustion plate (804), and the feeding rotating wheel (803) and the annular gear ring (805) are in meshing transmission.

Technical Field

The invention relates to the technical field of combustion furnace equipment, in particular to a biomass particle combustion furnace.

Background

The invention with publication number CN109780530A discloses a biomass particle combustion furnace with uniform biomass particle distribution and high combustion efficiency. The device comprises a material waiting bin, a feeding bin and a combustion bin, wherein the material waiting bin is of a V-shaped structure and is fixedly connected to the top of the feeding bin, the combustion bin is fixedly connected below the feeding bin, and a discharge hole is formed in one side of the feeding bin, which is close to the combustion bin; the bottom plate of the feeding bin is inclined downwards, and the biomass particles move towards the combustion bin through the inclined bottom plate; and a feeding plate which is matched with the bottom plate is arranged below the bottom plate, and the feeding plate moves along the inclined direction of the bottom plate through a linear driving mechanism. The linear driving mechanism comprises an air cylinder, an electric push rod or an oil cylinder. The invention has the disadvantage that the slag falling of biomass particles cannot be reduced.

Disclosure of Invention

The invention aims to provide a biomass particle combustion furnace which has the advantage of reducing slag falling of biomass particles.

The purpose of the invention is realized by the following technical scheme:

biomass particle fires burning furnace, including casing subassembly, compression subassembly, drive assembly, feeding subassembly, ejection of compact subassembly, drive assembly, year material subassembly and add material burning subassembly, compression subassembly sliding connection is on the casing subassembly, drive assembly rotates to be connected on the casing subassembly, compression subassembly and drive assembly meshing transmission, feeding subassembly sliding connection is on the casing subassembly, ejection of compact subassembly sliding connection is at the lower extreme of casing subassembly, drive assembly fixed connection is on the casing subassembly, drive assembly and drive assembly meshing transmission, feeding subassembly and ejection of compact subassembly all mesh the transmission with drive assembly, it is on the casing subassembly to carry material subassembly fixed connection, it meshes the transmission to carry material subassembly and drive assembly, it connects on the casing subassembly to add material burning subassembly.

The shell assembly comprises a combustion furnace, an ignition mechanism, a lower slideway, a feeding baffle, a forming barrel, an upper slideway and a communicating pipe, wherein the lower end of the combustion furnace is fixedly connected with the ignition mechanism, the lower slideway is fixedly connected to the combustion furnace, the feeding baffle is slidably connected to the lower slideway, the forming barrel is fixedly connected to the lower slideway, the upper slideway is fixedly connected to the upper end of the forming barrel, and the forming barrel is fixedly connected with the communicating pipe.

Compression assembly includes contour plate, waist type threaded rod, screwed pipe gear, spring plate and reset spring, and contour plate sliding connection is in the shaping bucket, fixedly connected with waist type threaded rod on the contour plate, and screwed pipe gear revolve connects on the shaping bucket, and waist type threaded rod and screwed pipe gear pass through screw thread transmission, and the spring plate rotates to be connected on the screwed pipe gear, fixedly connected with reset spring between the upper end of waist type threaded rod and the spring plate.

The transmission assembly comprises a first half-tooth gear, an interval tooth-missing gear and a transmission wheel, the first half-tooth gear is rotatably connected to the forming barrel, the interval tooth-missing gear and the transmission wheel are fixedly connected to the first half-tooth gear, and the first half-tooth gear and the threaded pipe gear are in meshing transmission.

The feeding assembly comprises a feeding fixed plate, a feeding spring, a feeding push plate and a feeding rack, the feeding fixed plate is fixedly connected to the upper slide way, the feeding spring is fixedly connected to the feeding fixed plate, the feeding push plate is connected to the upper slide way in a sliding mode, the feeding push plate is fixedly connected to the feeding spring, and the feeding rack is fixedly connected to the feeding push plate.

Ejection of compact subassembly includes ejection of compact fixed plate, ejection of compact cutting board, ejection of compact rack, ejection of compact push pedal and return piece, ejection of compact fixed plate fixed connection on the glide slope, ejection of compact cutting board sliding connection is on the glide slope, fixedly connected with spring between ejection of compact fixed plate and the ejection of compact cutting board, ejection of compact rack fixed connection is on ejection of compact cutting board, ejection of compact push pedal sliding connection is on ejection of compact cutting board, two return pieces of fixedly connected with in the ejection of compact push pedal.

The driving assembly comprises a driving motor, a worm gear, material conveying input teeth, symmetrical gears, a rack gear, a material conveying mounting plate, transmission input teeth and a transmission worm shaft, the driving motor is fixedly connected to the lower slideway, two worm gears are fixedly connected to an output shaft of the driving motor, the material conveying mounting plate is fixedly connected to the forming barrel, the symmetrical gears are rotatably connected to the material conveying mounting plate, the material conveying input teeth are fixedly connected to the symmetrical gears, the symmetrical gears are in meshing transmission with the worm gears at the lower end, the upper end and the lower end of the material conveying mounting plate are rotatably connected with the rack gear, the two rack gears are in meshing transmission with the symmetrical gears, a feeding rack and a discharging rack are respectively in meshing transmission with the two rack gears, the transmission worm shaft is rotatably connected to the upper slideway, the transmission input teeth are fixedly connected to the transmission worm shaft, the transmission input teeth are in meshing transmission, the transmission worm shaft is in meshing transmission with the transmission wheel.

The material loading assembly comprises a material loading baffle, a rotating gear plate and a material loading box, the material loading baffle is fixedly connected to the upper slideway, the rotating gear plate is rotatably connected to the material loading baffle, the material loading box is fixedly connected to the upper slideway, and the rotating gear plate and the material loading box are rotatably connected.

Add material combustion assembly and rotate the motor including the burning, add the material cam, add the material and rotate the wheel, ventilate combustion plate and annular ring gear, the burning rotates motor fixed connection on the glide slope, add the material cam and add the equal fixed connection of material rotation wheel on the output shaft that the motor was rotated in the burning, add the material cam and add material baffle line contact, the ventilation combustion plate rotates and connects in the burning furnace, annular ring gear fixed connection is on the ventilation combustion plate, add the material and rotate wheel and annular ring gear meshing transmission.

The biomass particle combustion furnace has the beneficial effects that: according to the biomass particle combustion furnace, the driving assembly can be engaged and driven by the driving assembly, and the material carrying assembly is engaged and driven by the driving assembly, so that biomass particles in the material carrying assembly automatically fall down, the compression assembly can be engaged and driven by the driving assembly to lift, the compression assembly can compress and mold the biomass particles, the situation of slag falling during combustion in the shell assembly is prevented, and the biomass particles directly fall into broken slag without being combusted to become waste materials, so that the waste of the biomass particles is avoided; can also slide through drive assembly meshing drive feeding subassembly and ejection of compact subassembly, realize that the feeding subassembly will carry the living beings granule propulsion shaping bucket of material subassembly whereabouts on going up and participate in compression molding, can also cut and promote the living beings granule after the shaping through ejection of compact subassembly, realize ejection of compact subassembly promotion living beings granule and provide the burning raw materials to the casing subassembly in, can also open through adding material burning subassembly and add the shutoff of material baffle to the glide slope, make things convenient for ejection of compact subassembly to the interior feed of casing subassembly, can also realize gradually adding living beings granule on the circumference of ventilation burning board through adding material burning subassembly after the shaping, make living beings granule can fully burn and reach the best utilization ratio.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

FIG. 1 is a schematic view of the overall structure of a biomass pellet-fired furnace of the present invention;

FIG. 2 is a schematic structural view of the housing assembly of the present invention;

FIG. 3 is a cross-sectional view of the housing assembly of the present invention;

FIG. 4 is a schematic view of the construction of the compression assembly of the present invention;

FIG. 5 is a schematic structural view of the transmission assembly of the present invention;

FIG. 6 is a schematic structural view of a feed assembly of the present invention;

FIG. 7 is a schematic structural view of the discharge assembly of the present invention;

FIG. 8 is a schematic structural view of the drive assembly of the present invention;

FIG. 9 is a schematic structural view of the loader assembly of the present invention;

fig. 10 is a schematic view of the construction of the stoker combustion assembly of the present invention.

In the figure: a housing assembly 1; a combustion furnace 101; an ignition mechanism 102; a lower chute 103; a charging baffle 104; a forming tub 105; an upper chute 106; communication pipe 107; a compression assembly 2; a contoured plate 201; a kidney-shaped threaded rod 202; a threaded pipe gear 203; a spring plate 204; a return spring 205; a transmission assembly 3; a first half-toothed gear 301; an interval missing tooth gear 302; a driving wheel 303; a feeding assembly 4; a feed holding plate 401; a feed spring 402; a feed pusher plate 403; a feed rack 404; a discharging component 5; a discharge fixing plate 501; an outfeed cutting board 502; a discharge rack 503; a discharge push plate 504; a carry-back block 505; a drive assembly 6; a drive motor 601; a worm gear 602; a material conveying input tooth 603; a symmetrical gear 604; a rack and pinion 605; a material handling mounting plate 606; the transmission input teeth 607; a drive worm shaft 608; a loading assembly 7; a loading baffle 701; a rotating gear plate 702; a material loading box 703; a charge combustion assembly 8; a combustion rotation motor 801; a material adding cam 802; a charging rotation wheel 803; a ventilated combustion plate 804; and an annular ring 805.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The first embodiment is as follows:

the biomass particle combustion furnace of the embodiment is described by combining figures 1-10, and comprises a shell assembly 1, a compression assembly 2, a transmission assembly 3, a feeding assembly 4, a discharging assembly 5, a driving assembly 6, a loading assembly 7 and a feeding combustion assembly 8, compression subassembly 2 sliding connection is on casing subassembly 1, drive assembly 3 rotates to be connected on casing subassembly 1, compression subassembly 2 and the transmission of 3 meshing of drive assembly, feeding subassembly 4 sliding connection is on casing subassembly 1, ejection of compact subassembly 5 sliding connection is at the lower extreme of casing subassembly 1, drive assembly 6 fixed connection is on casing subassembly 1, drive assembly 3 and the transmission of 6 meshing of drive assembly, feeding subassembly 4 and ejection of compact subassembly 5 all mesh the transmission with drive assembly 6, carry material subassembly 7 fixed connection on casing subassembly 1, carry material subassembly 7 and the transmission of 6 meshing of drive assembly, add material burning component 8 and connect on casing subassembly 1.

The driving assembly 3 can be engaged and driven through the driving assembly 6, and the material carrying assembly 7 can be engaged and driven through the driving assembly 3, so that the biomass particles in the material carrying assembly 7 can automatically fall down, the compression assembly 2 can be engaged and driven through the driving assembly 3 to lift, the compression assembly 2 can compress and form the biomass particles, the situation of slag falling during combustion in the shell assembly 1 is prevented, and the biomass particles directly fall into broken slag without being combusted to become waste materials, so that the waste of the biomass particles is avoided; can also slide through drive assembly 6 meshing drive feeding subassembly 4 and ejection of compact subassembly 5, realize that feeding subassembly 4 will carry the living beings granule of material subassembly 7 whereabouts to impel forming barrel 105 interior participation compression molding, can also cut and promote the living beings granule after the shaping through ejection of compact subassembly 5, realize ejection of compact subassembly 5 and promote living beings granule and provide the burning raw materials to casing subassembly 1 in, can also open the shutoff of adding material baffle 104 to lower slide 103 through adding material burning subassembly 8, make things convenient for ejection of compact subassembly 5 to the interior feed of casing subassembly 1, can also realize gradually adding living beings granule on the circumference of ventilation burner plate 804 with the living beings granule after the shaping through adding material burning subassembly 8, make living beings granule can fully burn and reach the best utilization ratio.

The second embodiment is as follows:

referring to fig. 1-10, the housing assembly 1 of the present embodiment includes a combustion furnace 101, an ignition mechanism 102, a lower chute 103, a feeding baffle 104, a forming barrel 105, an upper chute 106, and a communicating pipe 107, wherein the ignition mechanism 102 is fixedly connected to a lower end of the combustion furnace 101, the lower chute 103 is fixedly connected to the combustion furnace 101, the feeding baffle 104 is slidably connected to the lower chute 103, the forming barrel 105 is fixedly connected to the lower chute 103, the upper chute 106 is fixedly connected to an upper end of the forming barrel 105, and the communicating pipe 107 is fixedly connected to the forming barrel 105.

The third concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 10, the compression assembly 2 includes a contoured plate 201, a waist-shaped threaded rod 202, a threaded pipe gear 203, a spring plate 204 and a return spring 205, the contoured plate 201 is slidably connected in the forming barrel 105, the waist-shaped threaded rod 202 is fixedly connected to the contoured plate 201, the threaded pipe gear 203 is rotatably connected to the forming barrel 105, the waist-shaped threaded rod 202 and the threaded pipe gear 203 are in thread transmission, the spring plate 204 is rotatably connected to the threaded pipe gear 203, and the return spring 205 is fixedly connected between the upper end of the waist-shaped threaded rod 202 and the spring plate 204.

The fourth concrete implementation mode:

referring to fig. 1-10, the driving assembly 3 includes a first half-tooth gear 301, an interval missing-tooth gear 302 and a driving wheel 303, the first half-tooth gear 301 is rotatably connected to the forming drum 105, the interval missing-tooth gear 302 and the driving wheel 303 are both fixedly connected to the first half-tooth gear 301, and the first half-tooth gear 301 and the threaded pipe gear 203 are in mesh transmission.

The fifth concrete implementation mode:

referring to fig. 1-10, the feeding assembly 4 includes a feeding fixing plate 401, a feeding spring 402, a feeding pushing plate 403, and a feeding rack 404, the feeding fixing plate 401 is fixedly connected to the upper chute 106, the feeding spring 402 is fixedly connected to the feeding fixing plate 401, the feeding pushing plate 403 is slidably connected to the upper chute 106, the feeding pushing plate 403 is fixedly connected to the feeding spring 402, and the feeding rack 404 is fixedly connected to the feeding pushing plate 403.

The sixth specific implementation mode:

the present embodiment is described below with reference to fig. 1 to 10, the discharging assembly 5 includes a discharging fixing plate 501, a discharging cutting plate 502, a discharging rack 503, a discharging pushing plate 504 and a returning block 505, the discharging fixing plate 501 is fixedly connected to the lower slideway 103, the discharging cutting plate 502 is slidably connected to the lower slideway 103, a spring is fixedly connected between the discharging fixing plate 501 and the discharging cutting plate 502, the discharging rack 503 is fixedly connected to the discharging cutting plate 502, the discharging pushing plate 504 is slidably connected to the discharging cutting plate 502, and two returning blocks 505 are fixedly connected to the discharging pushing plate 504.

The seventh embodiment:

the present embodiment is described below with reference to fig. 1 to 10, the driving assembly 6 includes a driving motor 601, a worm gear 602, a material conveying input tooth 603, a symmetrical gear 604, a rack gear 605, a material conveying mounting plate 606, a transmission input tooth 607 and a transmission worm shaft 608, the driving motor 601 is fixedly connected to the lower chute 103, two worm gears 602 are fixedly connected to an output shaft of the driving motor 601, the material conveying mounting plate 606 is fixedly connected to the forming barrel 105, the symmetrical gear 604 is rotatably connected to the material conveying mounting plate 606, the material conveying input tooth 603 is fixedly connected to the symmetrical gear 604, the symmetrical gear 604 is in meshing transmission with the worm gear 602 at the lower end, the rack gears 605 are rotatably connected to the upper and lower ends of the material conveying mounting plate 606, the two rack gears 605 are in meshing transmission with the symmetrical gear 604, the feeding rack 404 and the discharging rack 503 are in meshing transmission with the two rack gears 605 respectively, the transmission worm shaft 608 is rotatably connected to the upper slideway 106, the transmission input tooth 607 is fixedly connected to the transmission worm shaft 608, the transmission input tooth 607 is in meshing transmission with the worm gear 602 at the upper end, and the transmission worm shaft 608 is in meshing transmission with the transmission wheel 303.

The specific implementation mode is eight:

the present embodiment is described below with reference to fig. 1 to 10, where the loading assembly 7 includes a loading baffle 701, a rotating gear plate 702, and a loading box 703, the loading baffle 701 is fixedly connected to the upper chute 106, the rotating gear plate 702 is rotatably connected to the loading baffle 701, the loading box 703 is fixedly connected to the upper chute 106, and the rotating gear plate 702 is rotatably connected to the loading box 703.

The specific implementation method nine:

the present embodiment is described below with reference to fig. 1 to 10, where the feeding combustion assembly 8 includes a combustion rotating motor 801, a feeding cam 802, a feeding rotating wheel 803, a ventilation combustion plate 804, and an annular gear ring 805, the combustion rotating motor 801 is fixedly connected to the down slide 103, the feeding cam 802 and the feeding rotating wheel 803 are both fixedly connected to an output shaft of the combustion rotating motor 801, the feeding cam 802 is in line contact with a feeding baffle 104, the ventilation combustion plate 804 is rotatably connected to the combustion furnace 101, the annular gear ring 805 is fixedly connected to the ventilation combustion plate 804, and the feeding rotating wheel 803 and the annular gear ring 805 are in meshing transmission.

The biomass particle combustion furnace of the invention has the use principle as follows: placing biomass particles in a material loading box 703, starting a driving motor 601, driving the driving motor 601 to drive two worm gears 602 to rotate, enabling the upper worm gear 602 to be meshed with a driving input tooth 607 to rotate, enabling the driving input tooth 607 to drive a driving worm shaft 608 to rotate, enabling the driving worm shaft 608 to be meshed with a driving wheel 303 to rotate, enabling the driving wheel 303 to drive a first half-tooth gear 301 and an interval missing tooth gear 302 to rotate, enabling the first half-tooth gear 301 to be meshed with a driving threaded pipe gear 203 to rotate, enabling the threaded pipe gear 203 to drive a waist-shaped threaded rod 202 to ascend and descend, enabling the waist-shaped threaded rod 202 to drive a pressure plate 201 to descend, enabling the waist-shaped threaded rod 202 to compress a return spring 205, enabling the first half-tooth gear 301 to be out of meshing with the threaded pipe gear 203 after the pressure plate 201 compresses the biomass particles, enabling the compressed return spring 205 to push, the water supply device can provide water mist for biomass particles through the communicating pipe 107, when the biomass particles are pressed down by the pressing plate 201, the pressing of the biomass particles is more compact, the biomass particles are prevented from directly passing through the ventilation holes to fall into the slag when the ventilation and combustion plate 804 burns, the biomass particles are prevented from directly mixing with the burned slag to be treated as the slag without participating in the combustion when the ventilation holes on the ventilation and combustion plate 804 are larger than the outward movement of the biomass particles, the resource waste is caused, when the first half-tooth gear 301 is not meshed with the threaded pipe gear 203, the spaced tooth-missing gear 302 starts to be meshed with the rotating gear plate 702, the rotating gear plate 702 rotates a quarter of a circle, the holes on the rotating gear plate 702 coincide with the holes on the loading baffle 701, and the biomass particles pass through the loading baffle 701 and the rotating gear plate 702 to fall into the upper slideway 106, the biomass particles are automatically added into the upward slideway 106, the interval tooth-lacking gear 302 has two parts of tooth-lacking, after the interval tooth-lacking gear 302 is meshed with the rotating gear plate 702 once, the interval quarter circumference is meshed with the rotating gear plate 702 again to drive the rotating gear plate to rotate one quarter, so that the rotating gear plate 702 stops the biomass raw material to pass through the material-carrying baffle plate 701, the biomass particles stop being automatically added into the upward slideway 106, the interval addition of the biomass particles can effectively prevent the biomass particles in the forming barrel 105 from being too much to cause the press plate 201 to fail to normally complete the compression forming of the biomass particles, the worm gear 602 at the lower end is meshed with and drives the material-conveying input tooth 603 to rotate, the material-conveying input tooth 603 drives the symmetrical gear 604 to shearer, the symmetrical gear 604 is meshed and drives the two rack gears 605 to rotate after the press plate 201 completes the descending process and is reset, the rack gear 605 at the upper end is meshed with and, the feeding rack 404 drives the feeding push plate 403 to slide, the feeding push plate 403 pulls the feeding spring 402, the feeding push plate 403 pushes biomass particles in the upper slide 106, the biomass particles in the upper slide 106 are pushed into the forming barrel 105, feeding for forming the biomass particles is realized, after the biomass particles are provided, the symmetrical gear 604 loses meshing with the rack gear 605, the stretched feeding spring 402 pulls the feeding push plate 403 to restore to the original position, when the symmetrical gear 604 is meshed with and drives the two rack gears 605, the rack gear 605 at the lower end is meshed with and drives the discharging rack 503 to slide, the discharging rack 503 drives the discharging cutting plate 502 to slide to cut the compressed biomass particles, the discharging cutting plate 502 drives the springs fixedly connected with the discharging cutting plate 502 to stretch, after the discharging cutting plate 502 cuts the compressed biomass particles, the discharging cutting plate 502 pushes the discharging push plate 504 to continuously slide to push the cut biomass particles, the biomass particles after cutting are pushed on the lower slideway 103, the compressed biomass particles in the lower slideway 103 are pushed into the combustion furnace 101 for combustion, after the rack gear 605 at the lower end is disengaged from the discharging rack 503, the discharging cutting plate 502 is reset under the drive of a stretching spring fixedly connected with the discharging cutting plate, after the discharging cutting plate 502 is reset for a certain distance, the discharging cutting plate 502 drives the discharging push plate 504 to reset through two reset blocks 505, before the discharging push plate 504 pushes the compressed biomass particles to slide, the combustion rotating motor 801 is started, the combustion rotating motor 801 drives the feeding rotating wheel 803 to rotate, the feeding rotating wheel 803 is engaged with the feeding rotating wheel 803 to drive the annular gear ring 805 to rotate, the annular gear ring 805 drives the ventilation combustion plate 804 to rotate, the combustion rotating motor 801 drives the feeding cam 802 to rotate, the feeding cam 802 jacks the feeding baffle 104 to rise, and the feeding baffle 104 loses the plugging of the lower slideway 103, discharging push plate 504 promotes the slip realization of compressed living beings granule and feeds in raw material on the ventilation burning board 804 in the burning furnace 101 this moment, can progressively add the living beings granule after the compression on the circumference of ventilation burning board 804, start ignition mechanism 102 and ignite the living beings granule, the intermittent type of ventilation burning board 804 rotates can so that the living beings granule after the burning carries out the whereabouts of disintegrating slag, can make the living beings granule carry out abundant burning, reach best combustion rate and utilization ratio.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.