CN112963846A - Linkage type inorganic waste incineration device with gravity driving structure - Google Patents

Abstract

The invention provides a linkage type inorganic waste incineration device with a gravity driving structure, relates to the technical field of incineration devices, and solves the problems that unpowered vibration slag removal is not realized through structural improvement, and unpowered wind power combustion supporting is realized through linkage. A linkage type inorganic waste incineration device with a gravity driving structure comprises an incineration box body and a stirring plate; burn through bolt fixedly connected with feeding structure on the box, and burn and install in the box and block the structure to burn and install the extrusion structure on the box. Because of drive plate B with burn board elastic contact, and drive plate B still adjusts well with the arch to drive plate B and arch have constituteed the vibrations structure of burning the board jointly, thereby can realize burning the vibrations of board and then having realized vibrations deashing when drive plate B follows slide bar C and moves rightly, and burn the wind-force combustion-supporting that produces when board up-and-down motion.

Description

Linkage type inorganic waste incineration device with gravity driving structure

Technical Field

The invention belongs to the technical field of incinerating devices, and particularly relates to a linkage type inorganic waste incinerating device with a gravity driving structure.

Background

The small town ratio of the country in which the country is removed and towned is continuously improved, and the existing township ratio of the country is far from meeting the requirement of national planning. The centralized living of rural population also leads to the centralized increase of production and domestic garbage, the serious garbage hexagonal problem occurs in small towns, and the garbage disposal and environmental pollution problems are more and more serious when a large amount of garbage is stacked on the roadside, the river side, the village side, the field side, the pond side and the house side.

As in application No.: CN201710150568.5, the garbage incineration device of the invention relates to an incinerator, comprising a dehydration extruder and a vertical spiral barrel garbage incinerator connected with the dehydration extruder, wherein the dehydration extruder consists of a feed hopper, an extrusion channel, an upper extrusion roller and a lower extrusion roller; the vertical spiral-tube garbage incinerator is composed of a cylindrical furnace body, a porous cylinder, a spiral porous material guide plate, a rotating shaft, a hearth grate and a motor. The garbage incineration device provided by the invention initiates a multi-stage constant-pressure extrusion dehydration process, adjusts the extrusion force level of a dehydration extruder according to the water content of garbage, and can adjust the extrusion force level to be high when the humidity is high. And due to the variability of garbage components, if hard objects (such as wood blocks, stones and the like) are met, the size of the gap can be automatically adjusted, so that the equipment can be prevented from being dead or damaged.

The inorganic refuse incineration apparatus similar to the above application has the following disadvantages at present:

one is that the incineration efficiency is low, and the reduction of the incineration efficiency is easily caused because the slag can not be removed in time in the incineration process of the existing device; moreover, although the existing device can realize wind power combustion supporting during incineration, the existing device is usually realized through a fan when realizing the wind power combustion supporting, the cost is high, unpowered vibration slag removal is not realized through structural improvement, and meanwhile, unpowered wind power combustion supporting is realized in a linkage manner.

Therefore, in view of the above, research and improvement are made for the existing structure and defects, and a linkage type inorganic waste incineration device with a gravity driving structure is provided, so as to achieve the purpose of higher practical value.

Disclosure of Invention

In order to solve the technical problems, the invention provides a linkage type inorganic waste incineration device with a gravity driving structure, which aims to solve the problems that the incineration efficiency is low in the prior art, and the incineration efficiency is reduced easily because the prior device cannot remove slag in time in the incineration process; moreover, although the existing device can realize wind power combustion supporting during incineration, the existing device is usually realized through a fan when realizing the wind power combustion supporting, the cost is high, unpowered vibration slag removal is not realized through structural improvement, and simultaneously, the problem of unpowered wind power combustion supporting is realized in a linkage manner.

The invention relates to a purpose and an effect of a linkage type inorganic waste incineration device with a gravity driving structure, which are achieved by the following specific technical means:

a linkage type inorganic waste incineration device with a gravity driving structure comprises an incineration box body and a stirring plate; the incineration box body is fixedly connected with a feeding structure through bolts, a blocking structure is arranged in the incineration box body, and an extrusion structure is arranged on the incineration box body; an incineration frame structure is arranged in the incineration box body, an air supply structure is arranged on the incineration box body, and a driving plate A is also arranged on the incineration box body; the poking plate is positioned below the discharge port, and the right end face of the poking plate is contacted with the head end of the sliding rod C above the poking plate; the head end of the upper sliding rod C is of a hemispherical structure, and the falling inorganic substance residues and the poking plate form an extrusion type structure of the sliding rod C; the incineration frame structure comprises through holes and bulges, the through holes are arranged on the incineration plate in a rectangular array shape, the bulges are welded on the incineration plate in a rectangular array shape, and the bulges are of semi-cylindrical structures; the driving structure comprises a driving plate B, and the driving plate B is welded on the sliding rod C; the driving plate B is in elastic contact with the incineration plate, the driving plate B is aligned to the protrusion, and the driving plate B and the protrusion jointly form a vibration structure of the incineration plate.

Furthermore, the feeding structure comprises a feeding bin, a feeding funnel, a pushing roller and a discharge port, the feeding bin is fixedly connected to the top of the incineration box body through a bolt, the feeding funnel is fixedly connected to the upper top of the feeding bin through a bolt, and the feeding funnel is communicated with the feeding bin; the feeding bin is rotatably connected with a pushing roller, and the pushing roller forms a pushing structure for inorganic crushed slag in the feeding bin.

Furthermore, the blocking structure comprises two sliding rods A and an elastic piece A, the two sliding rods A are connected to the incineration box body in a sliding mode, and a stop ring is welded on one sliding rod A above the two sliding rods A; an elastic piece A is sleeved on one sliding rod A above the sliding rod A, and the elastic piece A forms an elastic extension structure of the two sliding rods A.

Furthermore, the feeding structure also comprises a discharge hole, and the discharge hole is formed in the right side position of the bottom end face of the feeding bin; the blocking structure further comprises a blocking seat, the blocking seat is welded at the tail ends of the two sliding rods A, and the top end surface of the blocking seat is in contact with the bottom end surface of the feeding bin; when the sliding rod A is positioned at the initial position, the baffle seat is aligned with the discharge opening.

Furthermore, the incineration box body also comprises two poke rods, the two poke rods are symmetrically welded on a rotating shaft of the pushing roller, and the head ends of the two poke rods are of a hemispherical structure; the extrusion structure comprises a sliding seat and an extrusion rod, the sliding seat is welded on the incineration box body, the extrusion rod is connected onto the sliding seat in a sliding manner, and a rectangular plate welded at the head end of the extrusion rod is in contact with the poke rod; the blocking structure further comprises a stress block, the stress block is welded at the head ends of the two sliding rods A and is of a right-angle trapezoidal structure, and the inclined surface of the stress block is in elastic contact with the extrusion rod.

Furthermore, the incineration frame structure comprises four sliding rods B, an incineration plate and an elastic part B, wherein the four sliding rods B are welded on the bottom end face of the incineration box body, and each sliding rod B is of a stepped shaft-shaped structure; the four sliding rods B are connected with an incineration plate in a sliding mode, the four sliding rods B are sleeved with elastic pieces B, and the four elastic pieces B jointly form an elastic reset structure of the incineration plate.

Furthermore, the air supply structure comprises an elastic telescopic air bottle, a connecting pipe and a spray pipe, wherein the elastic telescopic air bottle is fixedly connected to the incineration box body, and the elastic telescopic air bottle is connected with the connecting pipe; the connecting pipe is connected with a spray pipe which is positioned in the incineration box body, and the elastic telescopic gas cylinder, the connecting pipe and the spray pipe jointly form a wind power combustion-supporting structure for incinerating substances on the incineration plate.

Further, the driving structure comprises a driving plate A, a sliding rod C, an elastic piece C and a poking plate, wherein the driving plate A is rotatably connected to the incineration box body; the number of the sliding rods C is two, and the two sliding rods C are connected to the incineration box body in a sliding mode; a stop ring is welded on the lower sliding rod C, an elastic piece C is sleeved on the lower sliding rod C, and the elastic piece C forms an elastic reset structure of the two sliding rods C; the tail ends of the two sliding rods C are welded with the poking plates, and the poking plates are in contact with the head ends of the elastic telescopic gas cylinders.

Compared with the prior art, the invention has the following beneficial effects:

through the feeding structure, block the structure, the extrusion structure, burn the cooperation setting of a structure and drive structure, at first can realize the inorganic matter intermittent type formula after smashing through the feeding structure with the cooperation that blocks the structure and drop, then the inorganic matter after dropping smashes drive plate A on, the extrusion drive through the structure of drive structure air feed structure can realize that wind-force is combustion-supporting, and stir the vibrations that can realize the residue and the wind-force is combustion-supporting to the vibrations formula that burns a structure through the drive structure, specifically as follows: firstly, the baffle seat is welded at the tail ends of the two sliding rods A, and the top end surface of the baffle seat is contacted with the bottom end surface of the feeding bin; when the sliding rod A is positioned at the initial position, the blocking seat is aligned with the discharge port, so that the shielding of the discharge port is realized; secondly, the sliding seat is welded on the incineration box body, the sliding seat is connected with an extrusion rod in a sliding mode, and a rectangular plate welded at the head end of the extrusion rod is in contact with the poke rod; the stress block is welded at the head ends of the two sliding rods A, is of a right-angle trapezoidal structure, and the inclined surface of the stress block is in elastic contact with the extrusion rod, so that when the pushing roller rotates, the extrusion rod is extruded through the poking rod, and then the stress block is extruded through the extrusion rod to realize the reciprocating motion of the blocking seat, thereby realizing intermittent feeding; thirdly, the connecting pipe is connected with a spray pipe which is positioned in the incineration box body, and the elastic telescopic gas cylinder, the connecting pipe and the spray pipe jointly form a wind power combustion-supporting structure of the incineration objects on the incineration plate, so that the combustion supporting of the incineration objects can be realized through gas sprayed out of the spray pipe when the elastic telescopic gas cylinder is extruded; a stop ring is welded on the lower sliding rod C, an elastic piece C is sleeved on the lower sliding rod C, and the elastic piece C forms an elastic reset structure of the two sliding rods C; the tail ends of the two sliding rods C are welded with the poking plates, and the poking plates are in contact with the head ends of the elastic telescopic gas cylinders, so that when the sliding rods C move rightwards, extrusion of the elastic telescopic gas cylinders can be achieved, and further wind power combustion supporting is achieved; fourthly, the head end of the upper sliding rod C is of a hemispherical structure, and the falling inorganic substance residues and the shifting plate form an extrusion type structure of the sliding rod C together, so that after the shifting plate is pressed by the intermittently falling inorganic substance residues, wind power combustion supporting can be realized by extruding the sliding rod C through the shifting plate; fifthly, the driving plate B is welded on the sliding rod C; the drive plate B is in elastic contact with the incineration plate, the drive plate B is aligned with the protrusion, and the drive plate B and the protrusion jointly form a vibration structure of the incineration plate, so that vibration of the incineration plate can be realized when the drive plate B moves rightwards along with the sliding rod C, vibration ash removal is realized, and wind power generated during up-and-down movement of the incineration plate is combustion-supporting.

Drawings

Fig. 1 is a schematic view of the present invention in a broken axial view.

Fig. 2 is a schematic axial view of the present invention in another direction of fig. 1.

Fig. 3 is a schematic front view of fig. 2 according to the present invention.

Fig. 4 is an enlarged schematic view of fig. 3 a according to the present invention.

Fig. 5 is an enlarged view of the structure of fig. 3B according to the present invention.

Fig. 6 is an enlarged view of the structure of fig. 3C according to the present invention.

Fig. 7 is an enlarged view of fig. 3D according to the present invention.

Fig. 8 is an enlarged view of fig. 3 at E according to the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. incinerating the box body; 2. a feed structure; 201. a feeding bin; 202. a feed hopper; 203. a pushing roller; 204. a discharge outlet; 205. a poke rod; 3. a barrier structure; 301. a slide bar A; 302. a blocking seat; 303. an elastic member A; 304. a stress block; 4. extruding the structure; 401. a sliding seat; 402. an extrusion stem; 5. an incineration frame structure; 501. a slide bar B; 502. incinerating the board; 503. an elastic member B; 504. a through hole; 505. a protrusion; 6. an air supply structure; 601. an elastic telescopic gas cylinder; 602. a connecting pipe; 603. a nozzle; 7. a drive structure; 701. a drive plate A; 702. a slide bar C; 703. an elastic member C; 704. a poking plate; 705. drive plate B.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 8:

the invention provides a linkage type inorganic waste incineration device with a gravity driving structure, which comprises an incineration box body 1 and a poking plate 704, wherein the incineration box body is provided with a driving plate; the incineration box body 1 is fixedly connected with a feeding structure 2 through bolts, a blocking structure 3 is arranged in the incineration box body 1, and an extrusion structure 4 is arranged on the incineration box body 1; an incineration rack structure 5 is arranged in the incineration box body 1, an air supply structure 6 is arranged on the incineration box body 1, and a driving plate A701 is further arranged on the incineration box body 1; referring to fig. 3, the striking plate 704 is located at a position below the discharge opening 204, and the right end surface of the striking plate 704 contacts the head end of the upper one of the slide bars C702; the head end of the upper sliding rod C702 is of a hemispherical structure, and the falling inorganic substance residues and the shifting plate 704 form an extrusion type structure of the sliding rod C702 together, so that after the shifting plate 704 is pressed by the intermittently falling inorganic substance residues, wind power combustion supporting can be realized by extruding the sliding rod C702 through the shifting plate 704; referring to fig. 3 and 6, the incineration rack structure 5 comprises through holes 504 and protrusions 505, the through holes 504 are opened on the incineration plate 502 in a rectangular array, the protrusions 505 are welded on the incineration plate 502 in a rectangular array, and the protrusions 505 are in a semi-cylindrical structure; the driving structure 7 comprises a driving plate B705, and the driving plate B705 is welded on a sliding rod C702; the driving plate B705 is in elastic contact with the incineration plate 502, the driving plate B705 is also aligned with the protrusion 505, and the driving plate B705 and the protrusion 505 jointly form a vibration structure of the incineration plate 502, so that when the driving plate B705 moves rightwards along with the sliding rod C702, vibration of the incineration plate 502 can be realized, and then vibration ash removal is realized, and wind power generated when the incineration plate 502 moves up and down is used for supporting combustion.

Referring to fig. 2, the feeding structure 2 comprises a feeding bin 201, a feeding funnel 202, a pushing roller 203 and a discharge port 204, the feeding bin 201 is fixedly connected to the top of the incineration chamber 1 through bolts, the feeding funnel 202 is fixedly connected to the top of the feeding bin 201 through bolts, and the feeding funnel 202 is communicated with the feeding bin 201; the feeding bin 201 is rotatably connected with a pushing roller 203, and the pushing roller 203 forms a pushing structure for inorganic crushed slag in the feeding bin 201.

Referring to fig. 2, the blocking structure 3 comprises two sliding rods a301 and an elastic member a303, the two sliding rods a301 are slidably connected to the incineration box body 1, and a baffle ring is welded on the upper sliding rod a 301; an elastic piece A303 is sleeved on the upper sliding rod A301, and the elastic piece A303 forms an elastic extension structure of the two sliding rods A301.

Referring to fig. 2, the feeding structure 2 further comprises a discharge outlet 204, and the discharge outlet 204 is opened at the right position of the bottom end surface of the feeding bin 201; the blocking structure 3 further comprises a blocking seat 302, the blocking seat 302 is welded at the tail ends of the two sliding rods A301, and the top end surface of the blocking seat 302 is in contact with the bottom end surface of the feeding bin 201; when the slide rod A301 is at the initial position, the baffle seat 302 is aligned with the discharge port 204, thereby realizing the shielding of the discharge port 204.

Referring to fig. 3, 4 and 5, the incineration box 1 further comprises two poke rods 205, the two poke rods 205 are symmetrically welded on the rotating shaft of the pushing roller 203, and the head ends of the two poke rods 205 are both of a hemispherical structure; the extrusion structure 4 comprises a sliding seat 401 and an extrusion rod 402, the sliding seat 401 is welded on the incineration box body 1, the extrusion rod 402 is connected on the sliding seat 401 in a sliding manner, and a rectangular plate welded at the head end of the extrusion rod 402 is in contact with the poke rod 205; the blocking structure 3 further comprises a force bearing block 304, the force bearing block 304 is welded at the head ends of the two sliding rods a301, the force bearing block 304 is of a right-angle trapezoid structure, and the inclined surface of the force bearing block 304 is in elastic contact with the extrusion rod 402, so that when the pushing roller 203 rotates, the extrusion rod 402 is extruded through the poking rod 205, then the force bearing block 304 is extruded through the extrusion rod 402, the reciprocating motion of the blocking seat 302 can be realized, and then the intermittent feeding is also realized.

Referring to fig. 3 and 6, the incineration frame structure 5 comprises four sliding rods B501, an incineration plate 502 and an elastic member B503, the number of the sliding rods B501 is four, and the four sliding rods B501 are welded on the bottom end surface of the incineration tank body 1, and each sliding rod B501 is a stepped shaft-shaped structure; the four sliding rods B501 are connected with an incineration plate 502 in a sliding mode, the four sliding rods B501 are sleeved with an elastic piece B503, and the four elastic pieces B503 jointly form an elastic reset structure of the incineration plate 502.

Referring to fig. 3, the air supply structure 6 includes an elastic telescopic air cylinder 601, a connecting pipe 602 and a nozzle 603, the elastic telescopic air cylinder 601 is fixedly connected to the incineration chamber body 1, and the elastic telescopic air cylinder 601 is connected to the connecting pipe 602; the connecting pipe 602 is connected with a spray pipe 603, the spray pipe 603 is located in the incineration box body 1, and the elastic telescopic gas cylinder 601, the connecting pipe 602 and the spray pipe 603 jointly form a wind power combustion-supporting structure for the incineration materials on the incineration plate 502, so that combustion-supporting of the incineration materials can be realized through gas sprayed out of the spray pipe 603 when the elastic telescopic gas cylinder 601 is extruded.

Referring to fig. 3, the driving structure 7 includes a driving plate a701, a sliding rod C702, an elastic member C703 and a toggle plate 704, the driving plate a701 being rotatably coupled to the incineration chamber 1; the number of the sliding rods C702 is two, and the two sliding rods C702 are both connected to the incineration box body 1 in a sliding manner; a stop ring is welded on the lower sliding rod C702, an elastic piece C703 is sleeved on the lower sliding rod C702, and the elastic piece C703 forms an elastic reset structure of the two sliding rods C702; the poking plate 704 is welded at the tail ends of the two sliding rods C702, and the poking plate 704 is in contact with the head ends of the elastic telescopic gas cylinders 601, so that when the sliding rods C702 move rightwards, extrusion of the elastic telescopic gas cylinders 601 can be achieved, and further wind power combustion supporting is achieved.

The specific use mode and function of the embodiment are as follows:

when the pushing roller 203 rotates, firstly, the baffle seat 302 is welded at the tail ends of the two sliding rods A301, and the top end surface of the baffle seat 302 is contacted with the bottom end surface of the feeding bin 201; when the sliding rod A301 is positioned at the initial position, the baffle seat 302 is aligned with the discharge port 204, so that the discharge port 204 is shielded; secondly, the sliding seat 401 is welded on the incineration box body 1, the sliding seat 401 is connected with an extrusion rod 402 in a sliding manner, and a rectangular plate welded at the head end of the extrusion rod 402 is in contact with the poke rod 205; the stress block 304 is welded at the head ends of the two sliding rods A301, the stress block 304 is in a right-angle trapezoid structure, and the inclined surface of the stress block 304 is in elastic contact with the extrusion rod 402, so that when the pushing roller 203 rotates, the extrusion rod 402 is extruded through the poke rod 205, and then the stress block 304 is extruded through the extrusion rod 402 to realize the reciprocating motion of the stop seat 302, thereby realizing intermittent feeding; thirdly, as the connecting pipe 602 is connected with the spray pipe 603, the spray pipe 603 is positioned in the incineration box body 1, and the elastic telescopic gas cylinder 601, the connecting pipe 602 and the spray pipe 603 jointly form a wind power combustion-supporting structure for the incineration materials on the incineration plate 502, the combustion-supporting of the incineration materials can be realized through the gas sprayed out of the spray pipe 603 when the elastic telescopic gas cylinder 601 is extruded; a stop ring is welded on the lower sliding rod C702, an elastic piece C703 is sleeved on the lower sliding rod C702, and the elastic piece C703 forms an elastic reset structure of the two sliding rods C702; the poking plate 704 is welded at the tail ends of the two sliding rods C702, and the poking plate 704 is in contact with the head ends of the elastic telescopic gas cylinders 601, so that when the sliding rods C702 move rightwards, extrusion of the elastic telescopic gas cylinders 601 can be realized, and further, wind power combustion supporting is realized; fourthly, the head end of the upper sliding rod C702 is of a hemispherical structure, and the falling inorganic substance residues and the shifting plate 704 form an extrusion type structure of the sliding rod C702 together, so that after the intermittently falling inorganic substance residues press the shifting plate 704, wind power combustion supporting can be realized by extruding the sliding rod C702 through the shifting plate 704; fifthly, the driving plate B705 is welded on the sliding rod C702; the driving plate B705 is in elastic contact with the incineration plate 502, the driving plate B705 is also aligned with the protrusion 505, and the driving plate B705 and the protrusion 505 jointly form a vibration structure of the incineration plate 502, so that when the driving plate B705 moves rightwards along with the sliding rod C702, vibration of the incineration plate 502 can be realized, and then vibration ash removal is realized, and wind power generated when the incineration plate 502 moves up and down is used for supporting combustion.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (8)

1. The utility model provides a coordinated type inorganic waste burns device with gravity drive structure which characterized in that: comprises an incineration box body (1) and a poking plate (704); the incinerator body (1) is fixedly connected with a feeding structure (2) through bolts, a blocking structure (3) is installed in the incinerator body (1), and an extrusion structure (4) is installed on the incinerator body (1); the incinerator body (1) is internally provided with an incineration rack structure (5), the incinerator body (1) is provided with an air supply structure (6), and the incinerator body (1) is also provided with a drive plate A (701); the poking plate (704) is positioned below the discharge port (204), and the right end face of the poking plate (704) is in contact with the head end of the upper sliding rod C (702); the head end of the upper sliding rod C (702) is of a hemispherical structure, and the falling inorganic residue and the poking plate (704) form a squeezing structure of the sliding rod C (702); the incineration frame structure (5) comprises through holes (504) and bulges (505), the through holes (504) are arranged on the incineration plate (502) in a rectangular array shape, the bulges (505) are welded on the incineration plate (502) in a rectangular array shape, and the bulges (505) are of a semi-cylindrical structure; the driving structure (7) comprises a driving plate B (705), and the driving plate B (705) is welded on a sliding rod C (702); the driving plate B (705) is in elastic contact with the incineration plate (502), the driving plate B (705) is also aligned with the bulge (505), and the driving plate B (705) and the bulge (505) jointly form a vibration structure of the incineration plate (502).

2. A linked inorganic waste incineration device having a gravity-driven structure as set forth in claim 1, wherein: the feeding structure (2) comprises a feeding bin (201), a feeding funnel (202), a pushing roller (203) and a discharge outlet (204), the feeding bin (201) is fixedly connected to the top of the incineration box body (1) through bolts, the upper top of the feeding bin (201) is fixedly connected with the feeding funnel (202) through bolts, and the feeding funnel (202) is communicated with the feeding bin (201); the feeding bin (201) is rotatably connected with a pushing roller (203), and the pushing roller (203) forms a pushing structure for inorganic crushed slag in the feeding bin (201).

3. A linked inorganic waste incineration device having a gravity-driven structure as set forth in claim 1, wherein: the blocking structure (3) comprises two sliding rods A (301) and an elastic piece A (303), the two sliding rods A (301) are connected to the incineration box body (1) in a sliding mode, and a stop ring is welded on one sliding rod A (301) above the two sliding rods A (301); an elastic piece A (303) is sleeved on one sliding rod A (301) above the sliding rod A, and the elastic piece A (303) forms an elastic extension structure of the two sliding rods A (301).

4. A linked inorganic waste incineration device having a gravity-driven structure as set forth in claim 1, wherein: the feeding structure (2) further comprises a discharge hole (204), and the discharge hole (204) is formed in the right side position of the bottom end face of the feeding bin (201); the blocking structure (3) further comprises a blocking seat (302), the blocking seat (302) is welded at the tail ends of the two sliding rods A (301), and the top end face of the blocking seat (302) is in contact with the bottom end face of the feeding bin (201); when the sliding rod A (301) is positioned at the initial position, the baffle seat (302) is aligned with the discharge opening (204).

5. A linked inorganic waste incineration device having a gravity-driven structure as set forth in claim 1, wherein: the incineration box body (1) further comprises two poke rods (205), the two poke rods (205) are symmetrically welded on a rotating shaft of the pushing roller (203), and the head ends of the two poke rods (205) are of a hemispherical structure; the extrusion structure (4) comprises a sliding seat (401) and an extrusion rod (402), the sliding seat (401) is welded on the incineration box body (1), the extrusion rod (402) is connected onto the sliding seat (401) in a sliding mode, and a rectangular plate welded to the head end of the extrusion rod (402) is in contact with the poke rod (205); the blocking structure (3) further comprises a force bearing block (304), the force bearing block (304) is welded at the head ends of the two sliding rods A (301), the force bearing block (304) is of a right-angle trapezoidal structure, and the inclined surface of the force bearing block (304) is in elastic contact with the extrusion rod (402).

6. A linked inorganic waste incineration device having a gravity-driven structure as set forth in claim 1, wherein: the incineration frame structure (5) comprises four sliding rods B (501), an incineration plate (502) and elastic pieces B (503), the number of the sliding rods B (501) is four, the four sliding rods B (501) are all welded on the bottom end face of the incineration box body (1), and each sliding rod B (501) is of a stepped shaft-shaped structure; four slide bar B (501) go up sliding connection and have one to burn board (502), and all cup joint an elastic component B (503) on four slide bar B (501), and four elastic component B (503) have constituteed the elasticity reset structure who burns board (502) jointly.

7. A linked inorganic waste incineration device having a gravity-driven structure as set forth in claim 1, wherein: the air supply structure (6) comprises an elastic telescopic air bottle (601), a connecting pipe (602) and a spray pipe (603), the elastic telescopic air bottle (601) is fixedly connected to the incineration box body (1), and the elastic telescopic air bottle (601) is connected with the connecting pipe (602); the connecting pipe (602) is connected with a spray pipe (603), the spray pipe (603) is positioned in the incineration box body (1), and the elastic telescopic gas cylinder (601), the connecting pipe (602) and the spray pipe (603) jointly form a wind power combustion-supporting structure of the incineration materials on the incineration plate (502).

8. A linked inorganic waste incineration device having a gravity-driven structure as set forth in claim 1, wherein: the driving structure (7) comprises a driving plate A (701), a sliding rod C (702), an elastic element C (703) and a poking plate (704), and the driving plate A (701) is rotatably connected to the incineration box body (1); the number of the sliding rods C (702) is two, and the two sliding rods C (702) are connected to the incineration box body (1) in a sliding manner; a stop ring is welded on the lower sliding rod C (702), an elastic piece C (703) is sleeved on the lower sliding rod C (702), and the elastic piece C (703) forms an elastic reset structure of the two sliding rods C (702); the tail ends of the two sliding rods C (702) are welded with a poking plate (704), and the poking plate (704) is in contact with the head end of the elastic telescopic gas cylinder (601).

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