CN117384657B - Industrial construction waste recycling and waste combustible material recycling and processing device - Google Patents

Abstract

The present invention relates to the technical field of recycling and treating waste combustibles for industrial construction waste, and discloses a recycling and treating device for waste combustibles for industrial construction waste, comprising an equipment housing, a driving motor is fixedly connected to the bottom of the equipment housing, an output shaft is fixedly connected to the output end of the driving motor, and a feeding door is arranged on the side wall of the equipment housing. The present invention arranges a stirring and exhausting mechanism, when the output end of the driving motor rotates, the output shaft is driven to rotate, the output shaft drives the rotating mechanism to rotate, the rotating mechanism rotates and drives the rotating rod to rotate, the rotating rod rotates and drives the stirring and extruding rod to rotate, the stirring and extruding rod rotates, the stirring and extruding rod rotates so that the accumulated raw materials are continuously stirred, and the cracking rate of the raw materials is improved.

Description

An industrial construction waste recycling and waste combustible material recycling and processing device

Technical Field

The invention relates to the technical field of industrial construction waste recycling and waste combustible material recycling and processing equipment, and specifically to an industrial construction waste recycling and processing device.

Background technique

There is a certain amount of waste combustibles with various complex components in the recycling of construction waste. A system for converting these waste combustibles in construction waste into clean fuel gas includes a temperature-controlled cracking furnace, primary purification, secondary purification, tertiary purification, primary separation, secondary separation, Roots blower and its connecting pipelines and subsequent supporting equipment. Various waste combustibles in the recycling of construction waste are sent to the temperature-controlled cracking furnace with a hopper after comprehensive raw material treatment, and are temperature-controlled and cracked in the furnace to produce complex gases. After two-stage purification and two-stage separation, three-stage purification is performed to form clean combustible gas, and debris, slag, dust, water vapor, acid liquid, complex tar, etc. are separated and discharged.

One of the systems for converting waste combustibles in construction waste into clean fuel gas is the most important of which is a temperature-controlled cracking furnace. The temperature-controlled cracking furnace needs to heat and pressurize the raw materials that have undergone comprehensive treatment to crack them, and convert the combustible substances in the raw materials into usable clean combustible gases and discharge them. When cracking raw materials, the industrial construction waste recycling and waste combustible material recovery and processing equipment under the existing technology usually directly feeds the raw materials into the device. There is no special structure inside the device to stir the raw materials being cracked, resulting in a slow cracking speed of the accumulated raw materials. At the same time, a large amount of combustible gas inside the cracking raw materials cannot be quickly discharged, which hinders further cracking of the raw materials.

Summary of the invention

The purpose of the present invention is to provide an industrial construction waste recycling and waste combustible material recovery and treatment device to solve the problems raised in the above background technology.

To solve the above technical problems, the present invention is achieved through the following technical solutions:

The present invention is an industrial construction waste recycling and waste combustible material recycling and processing device, comprising an equipment housing, a driving motor is fixedly connected to the bottom of the equipment housing, an output end of the driving motor is fixedly connected to an output shaft, a feeding door is arranged on the side wall of the equipment housing, a feeding handle is fixedly connected to the side wall of the feeding door, an equipment cover is fixedly connected to the top of the equipment housing, an air outlet interface is fixedly connected to the central axis of the equipment cover, a plurality of supporting legs are fixedly connected to the bottom of the equipment housing, and further comprising:

The rotating mechanism comprises a stirring rod fixedly connected to the end of the output shaft away from the driving motor, the stirring rod is a hollow structure, and the end of the stirring rod away from the output shaft is fixedly connected to a rotating frame.

Furthermore, the rotating mechanism also includes an annular gear 1 fixedly connected to the bottom of the rotating frame, a plurality of connecting columns are rotatably connected to the inner wall of the equipment housing, and a pinion is rotatably connected to the end of the connecting column away from the inner wall of the equipment housing, the pinion is meshed with annular gear 1, the bottom of the pinion is meshed with annular gear 2, and the bottom of the annular gear 2 is fixedly connected to the rotating frame.

Furthermore, a limiting mechanism is arranged inside the device housing, and the limiting mechanism comprises an annular groove formed on the inner wall of the rotating frame, a plurality of balls are rotatably connected in the annular groove, and a limiting ring is fixedly connected to the stirring rod.

Furthermore, a stirring and exhaust mechanism is arranged directly below the rotating mechanism, and the stirring and exhaust mechanism includes a plurality of rotating rods fixedly connected to the bottom of the rotating frame, a plurality of stirring and extruding rods fixedly connected to the rotating rods, a plurality of exhaust boxes fixedly connected to the side walls of the stirring rods, a plurality of exhaust columns fixedly connected to the side walls of the exhaust boxes, an exhaust rod is slidably connected to one end of the exhaust column away from the exhaust box, a plurality of air holes are opened on the side walls of the exhaust rods, and an extrusion semicircular block is fixedly connected to one end of the exhaust rod away from the exhaust column.

Furthermore, a linkage mechanism is provided inside the exhaust box, and the linkage mechanism includes a linkage rod fixedly connected to one end of the extrusion semicircular block close to the exhaust rod, an end of the linkage rod away from the extrusion semicircular block is fixedly connected to a sliding block, a fixed seat is fixedly connected to the bottom of the exhaust box, an end of the sliding block away from the linkage rod is fixedly connected to a return spring, and an end of the return spring away from the sliding block is fixedly connected to the fixed seat.

Furthermore, a stirring mechanism is arranged directly above the linkage mechanism, and the stirring mechanism comprises a plurality of protrusions fixedly connected to the side wall of the stirring rod, and a stirring base is slidably connected to the side wall of the stirring rod through the protrusions;

Among them, the bottom of the stirring base is fixedly connected with several connecting blocks, the end of the connecting block away from the stirring base is rotatably connected with a driving rod, the end of the driving rod away from the connecting block is rotatably connected to the sliding block, and the top of the stirring base is fixedly connected with several stirring rods.

Furthermore, a dust removal mechanism is arranged directly above the rotating mechanism, and the dust removal mechanism includes a plurality of extrusion columns fixedly connected to the top of the rotating frame, a closing cover is fixedly connected to the inner wall of the equipment housing, a plurality of outer covers are fixedly connected to the closing cover, and a fixing frame is fixedly connected to the inner wall of the outer cover;

The bottom of the outer cover is slidably connected with a dust cover, the bottom of the fixing frame is fixedly connected with a compression spring, the top of the fixing frame is fixedly connected with an induction spring, and one end of the induction spring away from the fixing frame is fixedly connected with a blocking piece.

Furthermore, a drainage mechanism is arranged directly above the dust removal mechanism, and the drainage mechanism includes a water receiving plate fixedly connected to the outer cover, and a water retaining cover is fixedly connected to the top of the closing cover, and the water retaining cover is arranged at the central axis of the equipment housing.

The present invention has the following beneficial effects:

(1) The present invention provides a stirring and exhausting mechanism. When the output end of the driving motor rotates, the output shaft is driven to rotate. The output shaft drives the rotating mechanism to rotate. The rotating mechanism drives the rotating rod to rotate. The rotating rod drives the stirring and extruding rod to rotate. The stirring and extruding rod can continuously stir the accumulated raw materials and improve the cracking rate of the raw materials. At the same time, the stirring rod rotates to drive the exhaust column on the exhaust box to rotate. The exhaust column rotates to drive the exhaust rod to rotate. At this time, the raw materials can be stirred and the recyclable gas generated after the cracking of the raw materials can be absorbed through the air holes on the exhaust rod. The recyclable gas enters the exhaust box through the exhaust rod and is discharged to the top of the device through the inside of the stirring rod. At the same time, the stirring and extruding rod rotates and squeezes the extruding semicircular block in the reverse rotation. At this time, the extruding semicircular block is squeezed and the exhaust rod is compressed inward along the exhaust column. At this time, the outer wall of the exhaust rod slides and rubs with the inner wall of the exhaust column, so that the raw materials on the exhaust rod can be scraped off, thereby preventing the raw materials on the exhaust rod from clogging the air holes, thereby affecting the exhaust efficiency of the stirring and exhausting mechanism.

(2) The present invention provides a linkage mechanism, so that the stirring extrusion rod rotates and is squeezed by the extrusion semicircular block in the opposite rotation. At this time, the extrusion semicircular block is squeezed to compress the exhaust rod inward along the exhaust column, and the extrusion semicircular block drives the linkage rod to slide inward. At this time, the linkage rod drives the sliding block to squeeze the reset spring inward, and the sliding block drives the driving rod to squeeze the stirring base upward. At this time, the stirring base slides upward along the convex block, and the rotation of the stirring rod drives the stirring base to rotate. The rotation of the stirring base drives the driving rod to rotate. The rotation of the driving rod can further stir the raw materials. At this time, the stirring base that slides up and down drives the driving rod to slide up and down. This arrangement is more conducive to fully stirring the raw materials being cracked, and is also more conducive to rapid discharge of gas in the raw materials.

(3) The present invention provides a dust removal mechanism. The driving motor drives the output shaft to rotate. The output shaft drives the stirring rod to rotate. The rotation of the stirring rod drives the extrusion column to rotate. The extrusion column rotates to squeeze the dust cover on the closed cover. At this time, the dust cover slides upward along the inner wall of the outer cover and shakes up and down under the action of the extrusion spring, which is conducive to shaking off the dust on the dust cover and achieving the beneficial effect of dust removal.

(4) The present invention provides a drainage mechanism. The recovered gas cracked from the bottom contains a large amount of water vapor. When the gas rises and is cooled, the water vapor will liquefy. At this time, a water receiving plate is provided to collect water droplets. In order to prevent water droplets from falling in the gas outlet interface, a water shield is provided to guide the water droplets into the water receiving plate to prevent the water droplets from dripping back onto the cracked raw materials, thereby effectively removing moisture from the gas.

Of course, any product implementing the present invention does not necessarily need to achieve all of the advantages described above at the same time.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the accompanying drawings required for describing the embodiments will be briefly introduced below. Obviously, the accompanying drawings described below are only some embodiments of the present invention. For ordinary technicians in this field, other accompanying drawings can be obtained based on these accompanying drawings without paying creative work.

Fig. 1 is a schematic diagram of the overall structure of the present invention;

FIG2 is a schematic diagram of the overall cross-sectional structure of the present invention;

FIG3 is an enlarged view of A in FIG2 of the present invention;

FIG4 is a schematic diagram of a partial structure of the present invention;

FIG5 is a schematic diagram of the overall structure of the stirring and exhausting mechanism of the present invention;

FIG6 is an enlarged view of B in FIG5 of the present invention;

FIG7 is an enlarged view of C in FIG2 of the present invention;

FIG8 is a schematic diagram of the overall structure of the stirring mechanism of the present invention;

FIG9 is a schematic diagram of a partial structure of a dust removal mechanism of the present invention;

FIG10 is a schematic diagram of a partial structure of a drainage mechanism of the present invention;

In the accompanying drawings, the components represented by the reference numerals are listed as follows:

In the figure: 1. Equipment housing; 11. Driving motor; 12. Output shaft; 13. Feed door; 14. Feed handle; 15. Equipment cover; 16. Air outlet interface; 17. Support leg; 2. Rotating mechanism; 201. Stirring stick; 202. Rotating frame; 203. Ring gear 1; 204. Connecting column; 205. Pinion; 206. Rotating frame; 207. Ring gear 2; 3. Limiting mechanism; 301. Ring groove; 302. Ball; 303. Limiting ring; 4. Stirring and exhausting mechanism; 401. Rotating rod; 402. Stirring and extruding rod; 403. Exhaust box; 404. Exhaust column; 405 , exhaust rod; 406, air vent; 407, extrusion semicircular block; 5, linkage mechanism; 501, linkage rod; 502, sliding block; 503, fixed seat; 504, reset spring; 6, stirring mechanism; 601, convex block; 602, stirring base; 603, connecting block; 604, driving rod; 605, stirring rod; 7, dust removal mechanism; 701, extrusion column; 702, closing cover; 703, outer cover; 704, fixing frame; 705, dust removal cover; 706, extrusion spring; 707, induction spring; 708, blocking piece; 8, drainage mechanism; 801, water receiving plate; 802, water retaining cover.

Detailed ways

The following will be combined with the drawings in the embodiments of the present invention to clearly and completely describe the technical solutions in the embodiments of the present invention. Obviously, the described embodiments are only part of the embodiments of the present invention, not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the present invention.

Example

Please refer to Figures 1 to 5. The present invention is an industrial construction waste recycling and waste combustible material recycling and processing device, including a device housing 1, a driving motor 11 is fixedly connected to the bottom of the device housing 1, an output end of the driving motor 11 is fixedly connected to an output shaft 12, a side wall of the device housing 1 is provided with a feed door 13, a side wall of the feed door 13 is fixedly connected to a feed handle 14, a top of the device housing 1 is fixedly connected to a device cover 15, a central axis of the device cover 15 is fixedly connected to an air outlet interface 16, a bottom of the device housing 1 is fixedly connected to a plurality of support legs 17, and further includes:

The rotating mechanism 2 includes a stirring rod 201 fixedly connected to the end of the output shaft 12 away from the driving motor 11. The stirring rod 201 is a hollow structure. The end of the stirring rod 201 away from the output shaft 12 is fixedly connected to a rotating frame 202. The function of this component is to add the raw materials after comprehensive treatment into the equipment through the feed door 13 on the equipment housing 1 in a certain amount, and the air receiving pipe is connected to the air outlet interface 16. Start the driving motor 11, and the output end of the driving motor 11 drives the output shaft 12 to rotate. The output shaft 12 drives the stirring rod 201 to rotate, and the rotation of the stirring rod 201 drives the rotating frame 202 to rotate.

The rotating mechanism 2 also includes a ring gear 1 203 fixedly connected to the bottom of the rotating frame 202, and the inner wall of the equipment housing 1 is rotatably connected to a plurality of connecting columns 204, and the end of the connecting column 204 away from the inner wall of the equipment housing 1 is rotatably connected to a pinion 205, and the pinion 205 is meshed with the ring gear 1 203, and the bottom of the pinion 205 is meshed with a ring gear 207, and the bottom of the ring gear 207 is fixedly connected to a rotating frame 206. The function of this component is that the rotation of the stirring rod 201 drives the rotating frame 202 to rotate, the rotation of the rotating frame 202 drives the ring gear 1 203 to rotate, the rotation of the ring gear 1 203 drives the pinion 205 to rotate, and the rotation of the pinion 205 drives the rotating frame 206 on the ring gear 207 to rotate. At this time, the rotation direction of the ring gear 207 is opposite to the rotation direction of the stirring rod 201.

A limiting mechanism 3 is arranged inside the device housing 1, and the limiting mechanism 3 includes an annular groove 301 opened on the inner wall of the rotating frame 206, and a plurality of balls 302 are rotatably connected in the annular groove 301, and a limiting ring 303 is fixedly connected to the stirring rod 201. The function of this component is that by setting the limiting mechanism 3, the rotating frame 206 can rotate on the stirring rod 201 through the balls 302 and will not be affected by the opposite rotation effect of the stirring rod 201. At the same time, the balls 302 are arranged to make the rotation of the rotating frame 206 smoother and more stable. At the same time, the limiting ring 303 is arranged to make the rotating frame 206 always rotate on the same horizontal plane.

A stirring and exhausting mechanism 4 is arranged directly below the rotating mechanism 2, and the stirring and exhausting mechanism 4 includes a plurality of rotating rods 401 fixedly connected to the bottom of the rotating frame 206, a plurality of stirring and extruding rods 402 are fixedly connected to the rotating rods 401, a plurality of exhaust boxes 403 are fixedly connected to the side walls of the stirring rods 201, a plurality of exhaust columns 404 are fixedly connected to the side walls of the exhaust boxes 403, an exhaust rod 405 is slidably connected to the end of the exhaust column 404 away from the exhaust box 403, a plurality of air holes 406 are provided on the side walls of the exhaust rods 405, an extrusion semicircular block 407 is fixedly connected to the end of the exhaust rod 405 away from the exhaust column 404, the function of this component is to set the stirring and exhausting mechanism 4, when the output end of the driving motor 11 rotates, the output shaft 12 is driven to rotate, the output shaft 12 drives the rotating mechanism 2 to rotate, the rotating mechanism 2 rotates and drives the rotating rod 401 to rotate, the rotating rod 401 rotates and drives the stirring and extruding rod 402 to rotate, and the stirring and extruding rod 40 2 rotation can make the accumulated raw materials continuously stirred, and improve the cracking rate of the raw materials. At the same time, the rotation of the stirring rod 201 drives the exhaust column 404 on the exhaust box 403 to rotate, and the rotation of the exhaust column 404 drives the exhaust rod 405 to rotate. At this time, while the raw materials are stirred, the recyclable gas generated after the cracking of the raw materials can be absorbed through the air vents 406 on the exhaust rod 405. The recyclable gas enters the exhaust box 403 through the exhaust rod 405, and then is discharged to the top of the equipment through the inside of the stirring rod 201. At the same time, the stirring and extruding rod 402 rotates and squeezes the extruding semicircular block 407 in the reverse rotation. At this time, the extruding semicircular block 407 is squeezed and the exhaust rod 405 is compressed inward along the exhaust column 404. At this time, the outer wall of the exhaust rod 405 and the inner wall of the exhaust column 404 slide and rub, and the raw materials on the exhaust rod 405 can be scraped off, so as to avoid the raw materials on the exhaust rod 405 blocking the air vents 406, thereby affecting the exhaust efficiency of the stirring and exhausting mechanism 4.

Example

The difference from Example 1 is that:

As shown in Figures 1 to 10, a linkage mechanism 5 is provided inside the exhaust box 403, and the linkage mechanism 5 includes a linkage rod 501 fixedly connected to one end of the extrusion semicircular block 407 close to the exhaust rod 405, and the end of the linkage rod 501 away from the extrusion semicircular block 407 is fixedly connected to a sliding block 502, and the bottom of the exhaust box 403 is fixedly connected to a fixed seat 503, and the end of the sliding block 502 away from the linkage rod 501 is fixedly connected to a return spring 504, and the end of the return spring 504 away from the sliding block 502 is fixedly connected to the fixed seat 503. The function of this component is to set up the linkage mechanism 5, so that the rotation of the stirring extrusion rod 402 and the extrusion semicircular block 407 in the reverse rotation are squeezed. At this time, the extrusion semicircular block 407 is squeezed to compress the exhaust rod 405 inward along the exhaust column 404, and the extrusion semicircular block 407 drives the linkage rod 501 to slide inward. At this time, the linkage rod 501 drives the sliding block 502 to squeeze the return spring 504 inward.

A stirring mechanism 6 is arranged directly above the linkage mechanism 5. The stirring mechanism 6 includes a plurality of protrusions 601 fixedly connected to the side wall of the stirring rod 201. A stirring base 602 is slidably connected to the side wall of the stirring rod 201 through the protrusions 601.

Among them, a plurality of connecting blocks 603 are fixedly connected to the bottom of the stirring base 602, and a driving rod 604 is rotatably connected to one end of the connecting block 603 away from the stirring base 602, and the driving rod 604 is rotatably connected to the sliding block 502 at one end away from the connecting block 603. A plurality of stirring rods 605 are fixedly connected to the top of the stirring base 602. The function of this component is that the sliding block 502 drives the driving rod 604 to squeeze the stirring base 602 upward. At this time, the stirring base 602 slides upward along the protrusion 601, and the rotation of the stirring rod 201 drives the stirring base 602 to rotate, and the rotation of the stirring base 602 drives the driving rod 604 to rotate. The rotation of the driving rod 604 can further stir the raw materials. At this time, the stirring base 602 sliding up and down drives the driving rod 604 to slide up and down. This arrangement is more conducive to fully stirring the raw materials being cracked, and is also more conducive to the rapid discharge of gas in the raw materials.

A dust removal mechanism 7 is arranged directly above the rotating mechanism 2. The dust removal mechanism 7 includes a plurality of extrusion columns 701 fixedly connected to the top of the rotating frame 202. A closing cover 702 is fixedly connected to the inner wall of the device housing 1. A plurality of outer covers 703 are fixedly connected to the closing cover 702. A fixing frame 704 is fixedly connected to the inner wall of the outer cover 703.

Among them, the bottom of the outer cover 703 is slidably connected with a dust removal cover 705, the bottom of the fixed frame 704 is fixedly connected with an extrusion spring 706, the top of the fixed frame 704 is fixedly connected with an induction spring 707, and the end of the induction spring 707 away from the fixed frame 704 is fixedly connected with a blocking piece 708. The function of this component is to set the dust removal mechanism 7, drive the motor 11 to drive the output shaft 12 to rotate, the output shaft 12 drives the stirring rod 201 to rotate, the rotation of the stirring rod 201 drives the extrusion column 701 to rotate, and the extrusion column 701 rotates to squeeze the dust removal cover 705 on the closing cover 702. At this time, the dust removal cover 705 slides upward along the inner wall of the outer cover 703, and shakes up and down under the action of the extrusion spring 706, which is conducive to shaking off the dust on the dust removal cover 705, thereby achieving the beneficial effect of dust removal. At the same time, the pressure generated by the gas in the equipment housing 1 is greater than the elastic force of the induction spring 707, causing the blocking piece 708 to move upward, and the recovered gas passes through the outer cover 703.

A drainage mechanism 8 is arranged directly above the dust removal mechanism 7, and the drainage mechanism 8 includes a water receiving plate 801 fixedly connected to the outer cover 703, and a water shield 802 is fixedly connected to the top of the closing cover 702, and the water shield 802 is arranged at the central axis of the equipment housing 1. The function of this component is to set the drainage mechanism 8, and the recovered gas cracked from the bottom contains a large amount of water vapor. When the gas rises and is cooled, the water vapor will liquefy. At this time, the water receiving plate 801 is set to collect water droplets. In order to avoid water droplets falling in the gas outlet interface 16, the water shield 802 is set to guide the water droplets into the water receiving plate 801 to prevent the water droplets from dripping again and onto the cracked raw materials, which is beneficial to remove moisture from the gas.

A specific application of this embodiment is:

If the industrial construction waste recycling and waste combustible material recycling and processing device is to be used, firstly, the raw materials after comprehensive treatment are added into the equipment through the feed door 13 on the equipment housing 1 in a certain amount, the air pipe is connected to the air outlet interface 16, the drive motor 11 is started, and the output end of the drive motor 11 drives the output shaft 12 to rotate. The output shaft 12 drives the stirring rod 201 to rotate, the stirring rod 201 rotates and drives the rotating frame 202 to rotate, the rotating frame 202 rotates and drives the ring gear 203 to rotate, the ring gear 203 rotates and drives the small gear 205 to rotate, and the small gear 20 5 rotates to drive the rotating frame 206 on the ring gear 207 to rotate. At this time, the rotating direction of the ring gear 207 is opposite to the rotating direction of the stirring rod 201. By setting the limiting mechanism 3, the rotating frame 206 can rotate on the stirring rod 201 through the ball 302 and is not affected by the reverse rotation effect of the stirring rod 201. At the same time, the ball 302 can make the rotating frame 206 rotate more smoothly and stably. At the same time, the limiting ring 303 can make the rotating frame 206 always rotate on the same horizontal plane. By setting the stirring exhaust mechanism 4, when the output end of the driving motor 11 rotates The output shaft 12 drives the rotating mechanism 2 to rotate, the rotating mechanism 2 drives the rotating rod 401 to rotate, the rotating rod 401 drives the stirring extrusion rod 402 to rotate, the stirring extrusion rod 402 can continuously stir the accumulated raw materials, and improve the cracking rate of the raw materials. At the same time, the stirring rod 201 drives the exhaust column 404 on the exhaust box 403 to rotate, and the exhaust column 404 drives the exhaust rod 405 to rotate. At this time, the raw materials can be stirred and the recyclable gas generated after the cracking of the raw materials can be discharged through the air holes 404 on the exhaust rod 405. 6 absorption, the recyclable gas enters the exhaust box 403 through the exhaust rod 405, and then is discharged to the top of the device through the stirring rod 201. At the same time, the stirring and extruding rod 402 rotates and is extruded by the extruding semicircular block 407 in the reverse rotation. At this time, the extruding semicircular block 407 is squeezed and the exhaust rod 405 is compressed inward along the exhaust column 404. At this time, the outer wall of the exhaust rod 405 and the inner wall of the exhaust column 404 slide and rub, and the raw materials on the exhaust rod 405 can be scraped off, so as to avoid the raw materials on the exhaust rod 405 blocking the air vent 406, thereby affecting the exhaust efficiency of the stirring exhaust mechanism 4;

By setting the linkage mechanism 5, the stirring and extruding rod 402 rotates and is squeezed by the extruding semicircular block 407 in the reverse rotation. At this time, the extruding semicircular block 407 is squeezed to compress the exhaust rod 405 inward along the exhaust column 404, and the extruding semicircular block 407 drives the linkage rod 501 to slide inward. At this time, the linkage rod 501 drives the sliding block 502 to squeeze the return spring 504 inward, and the sliding block 502 drives the driving rod 604 to squeeze the stirring base 602 upward. At this time, the stirring base 602 slides upward along the protrusion 601, and the stirring rod 201 rotates to drive the stirring base 602 to rotate, and the stirring base 602 rotates to drive the driving rod 604 to rotate. The driving rod 604 rotates to further stir the raw materials. At this time, the stirring base 602 sliding up and down drives the driving rod 604 to slide up and down. This arrangement is more conducive to fully stirring the raw materials being cracked, and is also more conducive to the rapid discharge of gas in the raw materials. By setting the dust removal mechanism 7, the driving motor 11 drives the output The shaft 12 rotates, and the output shaft 12 drives the stirring rod 201 to rotate. The rotation of the stirring rod 201 drives the squeezing column 701 to rotate. The squeezing column 701 rotates and squeezes the dust cover 705 on the closed cover 702. At this time, the dust cover 705 slides upward along the inner wall of the outer cover 703, and shakes up and down under the action of the squeezing spring 706, which is conducive to shaking off the dust on the dust cover 705, thereby achieving the beneficial effect of dust removal. At the same time, the pressure generated by the gas in the equipment housing 1 is greater than the elastic force of the induction spring 707, which makes the blocking plate 708 move upward. At this time, the recovered gas passes through the outer cover 703. By setting the drainage mechanism 8, the recovered gas cracked from the bottom contains a large amount of water vapor. When the gas rises and encounters cold, the water vapor will liquefy. At this time, a water receiving plate 801 is set to collect water droplets. In order to avoid water droplets falling in the gas outlet interface 16, a water retaining cover 802 is set to guide the water droplets into the water receiving plate 801 to prevent the water droplets from dripping back onto the cracked raw materials, which is beneficial to remove moisture from the gas.

The preferred embodiments of the present invention disclosed above are only used to help illustrate the present invention. The preferred embodiments do not describe all the details in detail, nor do they limit the invention to the specific implementation methods described. Obviously, many modifications and changes can be made according to the content of this specification. This specification selects and specifically describes these embodiments in order to better explain the principles and practical applications of the present invention, so that those skilled in the art can understand and use the present invention well. The present invention is limited only by the claims and their full scope and equivalents.

Claims (3)

1. The utility model provides an industrial construction waste retrieves abandonment combustible material recovery processing apparatus, includes equipment shell (1), the bottom fixedly connected with driving motor (11) of equipment shell (1), the output fixedly connected with output pivot (12) of driving motor (11), the lateral wall of equipment shell (1) is provided with feed gate (13), the lateral wall fixedly connected with feeding handle (14) of feed gate (13), the top fixedly connected with equipment cover (15) of equipment shell (1), the axis department fixedly connected with interface (16) of giving vent to anger of equipment cover (15), the bottom fixedly connected with supporting leg (17) of equipment shell (1), its characterized in that still includes:

the stirring rod (201) is of a hollow structure, and one end of the stirring rod (201) far away from the output rotating shaft (12) is fixedly connected with a rotating frame (202);

The rotating mechanism (2) further comprises a first ring gear (203) fixedly connected to the bottom of the rotating frame (202), a plurality of connecting columns (204) are rotatably connected to the inner wall of the equipment shell (1), a pinion (205) is rotatably connected to one end, far away from the inner wall of the equipment shell (1), of each connecting column (204), the pinion (205) is meshed with the first ring gear (203), a second ring gear (207) is meshed with the bottom of the pinion (205), and a rotating frame (206) is fixedly connected to the bottom of the second ring gear (207);

a limiting mechanism (3) is arranged in the equipment shell (1), the limiting mechanism (3) comprises a ring groove (301) formed in the inner wall of the rotating frame (206), a plurality of balls (302) are rotationally connected in the ring groove (301), and a limiting ring (303) is fixedly connected on the stirring rod (201);

The stirring and exhausting mechanism (4) is arranged right below the rotating mechanism (2), the stirring and exhausting mechanism (4) comprises a plurality of rotating rods (401) fixedly connected to the bottom of the rotating frame (206), a plurality of stirring extrusion rods (402) are fixedly connected to the rotating rods (401), a plurality of exhaust boxes (403) are fixedly connected to the side walls of the stirring rods (201), a plurality of exhaust columns (404) are fixedly connected to the side walls of the exhaust boxes (403), an exhaust rod (405) is slidably connected to one end, far away from the exhaust boxes (403), of each exhaust column (404), a plurality of ventilation holes (406) are formed in the side walls of the exhaust rods (405), and extrusion semicircular blocks (407) are fixedly connected to one end, far away from the exhaust columns (404), of each exhaust rod (405).

The novel exhaust box is characterized in that a linkage mechanism (5) is arranged in the exhaust box (403), the linkage mechanism (5) comprises a linkage rod (501) fixedly connected to one end of the extrusion semicircular block (407) close to the exhaust rod (405), a sliding block (502) is fixedly connected to one end of the linkage rod (501) away from the extrusion semicircular block (407), a fixed seat (503) is fixedly connected to the bottom of the exhaust box (403), a return spring (504) is fixedly connected to one end of the sliding block (502) away from the linkage rod (501), and one end of the return spring (504) away from the sliding block (502) is fixedly connected with the fixed seat (503);

A stirring mechanism (6) is arranged right above the linkage mechanism (5), the stirring mechanism (6) comprises a plurality of protruding blocks (601) fixedly connected to the side wall of the stirring rod (201), and a stirring base (602) is connected to the side wall of the stirring rod (201) in a sliding manner through the protruding blocks (601);

the stirring device comprises a stirring base (602), and is characterized in that a plurality of connecting blocks (603) are fixedly connected to the bottom of the stirring base (602), one end, far away from the stirring base (602), of each connecting block (603) is rotationally connected with a driving rod (604), one end, far away from the connecting blocks (603), of each driving rod (604) is rotationally connected with a sliding block (502), and a plurality of stirring rods (605) are fixedly connected to the top of the stirring base (602).

2. The industrial construction waste recycling waste combustible recycling device according to claim 1, wherein: a dust removing mechanism (7) is arranged right above the rotating mechanism (2), the dust removing mechanism (7) comprises a plurality of extrusion columns (701) fixedly connected to the top of the rotating frame (202), a sealing cover (702) is fixedly connected to the inner wall of the equipment shell (1), a plurality of outer covers (703) are fixedly connected to the sealing cover (702), and a fixing frame (704) is fixedly connected to the inner wall of the outer covers (703);

The dust removal device comprises a dust removal cover (705) and is characterized in that the bottom of the outer cover (703) is connected with the dust removal cover in a sliding mode, an extrusion spring (706) is fixedly connected with the bottom of the fixing frame (704), an induction spring (707) is fixedly connected with the top of the fixing frame (704), and a blocking piece (708) is fixedly connected with one end, far away from the fixing frame (704), of the induction spring (707).

3. The industrial construction waste recycling waste combustible recycling device according to claim 2, wherein: the dust removal mechanism is characterized in that a drainage mechanism (8) is arranged right above the dust removal mechanism (7), the drainage mechanism (8) comprises a water receiving plate (801) fixedly connected to a housing (703), a water retaining cover (802) is fixedly connected to the top of the sealing cover (702), and the water retaining cover (802) is arranged at the center shaft of the equipment shell (1).