CN218442314U - Wind control device of small-sized modularized multi-garbage cooperative processing system - Google Patents

Abstract

The utility model discloses a wind control device of a small-sized modularized multi-garbage co-processing system, which is positioned at the rear end of an incinerator grate device and comprises a primary wind control device, a secondary wind control device, a main draft pipe, a primary wind draft branch pipe, a secondary wind draft branch pipe, a primary and secondary wind draft connecting pipe section, a primary and secondary wind draft inlet; the primary air control device is arranged in the ash falling hopper, and the secondary air control device is erected on the flue gas secondary combustion chamber; 1. two ends of the secondary air draft connecting pipe section are respectively connected to the primary air draft opening, the secondary air draft opening and the draft main pipe; 1. the secondary air suction opening is positioned inside the feeding pretreatment module; the main draft pipe is connected to the primary air control device and the secondary air control device through the primary air draft branch pipe and the secondary air draft branch pipe respectively. The utility model discloses a design that a fan controlled two ash buckets to supply air can be according to the accurate air supply of the interior amount of wind demand of stove.

Description

Wind control device of small-sized modularized multi-garbage cooperative processing system

Technical Field

The utility model belongs to the technical field of refuse treatment, concretely relates to wind accuse device of multiple rubbish concurrent processing system of small-size modularization.

Background

With the rapid development of production and the rapid rise of economy, the phenomenon of refuse city wall is becoming more and more serious. Meanwhile, with the continuous promotion of the industrialization process, the amount of industrial solid waste, sewage, sludge and other wastes is continuously enlarged, and the necessity of harmless treatment of various wastes is more and more prominent.

At present, a waste incineration power generation project has large-scale benefits and develops towards a large-scale and integrated direction, meanwhile, a small-scale, modularized, high-flexibility and strong-adaptability miniaturized movable waste incineration system does not form a mature market scale, but the demands of inconvenient traffic, small and discontinuous waste treatment amount and harmless treatment of various types of waste are quite large, so that the small-scale modularized multi-type waste cooperative treatment system is a development direction with wide market and urgent demand.

The primary air control system in the prior art mostly controls the air supply amount in an ash hopper for one fan, so that a plurality of fans are required to be equipped for the incinerator, if the primary air control system is a fixed construction project, the space of a factory building is sufficient, but for the incinerator system with limited space, the large space occupied by the number of the fans is a great problem. Obviously, the traditional primary air fan arrangement is difficult to meet the requirements of small-sized modularized multi-garbage cooperative treatment systems. For example, CN206944177U discloses a garbage incinerator ash bucket and garbage incinerator, comprising: the ash bucket comprises an ash bucket main body and an air inlet main pipe; the air inlet main pipe comprises an air inlet main pipe inserted into the ash bucket main body and an air outlet device arranged on the side surface of the air inlet main pipe and located inside the ash bucket main body. The device can't compromise a plurality of ash buckets and correspond the wind demand of giving of the primary air in burning the grate, can't solve the demand that the accurate air inlet rate of adjusting of primary air, and has the too big problem of primary air system occupation space.

SUMMERY OF THE UTILITY MODEL

The utility model provides a not enough to prior art, the utility model provides a wind accuse device of multiple rubbish cooperative processing system of small-size modularization adopts a fan control two ash falling buckets to give the design of wind, thereby survey the feedback signal of interior burning situation feedback to intelligent control terminal in the stove according to burning monitoring in the burning furnace, decides the total amount of wind of giving of certain section fan, again according to the rotation of the driving motor of each air-out control pipeline of burning condition control that every ash falling bucket corresponds to the accurate wind of giving of the amount of wind demand in the stove.

The utility model discloses a realize through following technical scheme:

a wind control device of a small-sized modularized multi-garbage co-processing system comprises a feeding pre-processing module and an incineration processing module of the small-sized modularized multi-garbage co-processing system, wherein the incineration processing module comprises an incinerator grate device and a flue gas secondary combustion chamber, the bottom of the incinerator grate device is provided with a plurality of ash falling hoppers, the wind control device is positioned at the rear end of the incinerator grate device, and the wind control device comprises a primary wind control device, a secondary wind control device, a main wind draft pipe, a primary wind draft branch pipe, a secondary wind draft branch pipe, a primary wind draft connecting pipe section, a secondary wind draft connecting pipe section, a primary wind draft connecting pipe section and a secondary wind draft opening; the primary air control device is arranged in the ash falling hopper, and the secondary air control device is erected on the flue gas secondary combustion chamber; two ends of the primary air draft connecting pipe section and the secondary air draft connecting pipe section are respectively connected to the primary air draft opening, the secondary air draft opening and the draft main pipe; the primary air suction opening and the secondary air suction opening are positioned in the feeding pretreatment module; the main draft pipe is respectively connected with a primary air draft branch pipe and a secondary air draft branch pipe; the primary air exhaust branch pipe is connected to the primary air control device, and the secondary air exhaust branch pipe is connected to the secondary air control device;

the primary air control device comprises a primary air outlet control pipeline, a primary air outlet elbow and a primary fan; the number of the primary air outlet control pipelines is the same as that of the ash falling buckets, and the number of the primary air outlet bent pipes is the same as that of the primary fans and is half of that of the primary air outlet control pipelines; the primary air outlet control pipelines are respectively arranged in parallel in the ash falling hoppers, and two adjacent primary air outlet control pipelines are connected in series and connected to an air outlet of a primary fan through a primary air outlet bent pipe; an air inlet of the primary fan is connected with a primary air exhaust branch pipe;

the secondary air control device comprises a secondary air annular pipeline, an air outlet nozzle, a secondary air outlet bent pipe and a secondary fan; the secondary air annular pipeline is erected on the outer wall of the pipeline of the flue gas secondary combustion chamber for a circle; a plurality of holes are formed in the periphery of the outer wall of the pipeline of the flue gas secondary combustion chamber, a plurality of air outlet nozzles are arranged on the secondary air annular pipeline, the plurality of air outlet nozzles are in one-to-one correspondence with the plurality of holes, and the end parts of the air outlet nozzles are inserted into the holes; the secondary air annular pipeline is connected to an air outlet of the secondary air fan through a secondary air outlet bent pipe, and an air inlet of the secondary air fan is connected with a secondary air exhaust branch pipe.

Preferably, the primary air outlet control pipeline comprises a primary air outlet pipe section, an air outlet wind shielding switch and a driving motor; two rows of air outlets are uniformly arranged at the middle section part of the primary air outlet pipe section, and the two rows of air outlets are symmetrically arranged at two sides of the primary air outlet pipe section; a plurality of sliding block rails are arranged between two adjacent air outlets and at two ends of the primary air outlet pipe section, and a plurality of air outlet wind-shielding switch support frames are arranged on the circumference where the sliding block rails are located; the air outlet wind-shielding switch comprises an inner frame body, an outer frame body and a sliding block, wherein the inner frame body is fixedly connected with the outer frame body through the sliding block; the sliding block is arranged in the sliding block track and can move along the sliding block track; the inner frame body is tightly attached to the inner wall of the primary air outlet pipe section, and a transverse plate structure is arranged at each air outlet of the inner frame body and used for shielding the air outlet; the outer frame body is of a plurality of annular structures, and is erected on the outer wall of the primary air outlet pipe section through a plurality of air outlet wind-shielding switch support frames, wherein the outer rings of the annular structures erected at two ends of the primary air outlet pipe section are arranged into gear structures; the number of the driving motors is 2, the driving motors are respectively and fixedly arranged at two ends of the primary air outlet pipe section, and the gear structure is meshed with a gear of the driving motor; the driving motor drives the outer frame body to move through the gear structure, and then drives the whole air outlet wind shielding switch to move along the sliding block track.

Preferably, the driving motors are positioned outside the ash falling hopper and are symmetrically arranged.

Preferably, the number of the primary air draft branch pipes is the same as that of the primary air blowers, and each primary air draft branch pipe corresponds to one primary air blower.

Preferably, the system further comprises an intelligent control system, the intelligent control system takes an intelligent control terminal as a center and takes a feedback signal of a combustion monitoring system in the incinerator as a basis, and the intelligent control terminal is respectively connected with and controls the primary air fan, the secondary air fan and the driving motors of the primary air outlet pipe sections.

The utility model has the advantages as follows:

(1) The utility model discloses a design that two ash buckets of a fan control were given wind, thereby survey the feedback signal that the interior burning situation fed back to intelligent control terminal in the stove according to burning monitoring in the burning furnace, decide the total amount of wind of giving of a certain section primary air fan, again according to the rotation of the driving motor of each primary air-out pipeline section of the burning condition control that every ash bucket corresponds to give wind according to the interior amount of wind demand accuracy of stove.

(2) The utility model discloses there is complete control logic, the burning situation in the incinerator is discerned and is caught by combustion monitoring system, and give intelligent control terminal with signal feedback, intelligent control terminal judges out the amount of wind that gives of each partial primary air and overgrate air through handling, and the amount of wind is given to the totality of further control primary air fan, driving motor and the overgrate fan of primary air-out pipeline section in each ash bucket of simultaneous control, thereby the primary air and the overgrate air demand that burn the grate that each ash bucket of accurate control corresponds.

Drawings

FIG. 1 is a three-dimensional schematic view of a small modular multiple waste co-processing system;

in fig. 1: 1. a central control module; 2. a mobile generator set module; 3. a feed pre-treatment module; 4. an incineration processing module; 5. a flue gas waste heat utilization module; 6. a flue gas purification module; 7. a sewage treatment module; 8. a system coupling customization module; 9. loading the mobile module;

FIG. 2 is a schematic diagram showing the equipment configuration of a feed pretreatment module and an incineration module;

in FIG. 2: l01, primary air draft and secondary air draft connecting pipe sections; l02, a solid waste feeding connecting section; l03, connecting a sludge feeding pipe section; 301. a secondary screw material conveyor; 302. a sludge direct-fired material conveying pipeline; 303. a primary air suction opening and a secondary air suction opening; 304. a screw pump; 403. a sludge feeding device at the top of the hearth; 404. a material distributing device is arranged in front of the incinerator; 405. an incinerator hearth; 406. an incinerator grate unit; 407. a dust falling hopper; 408. a slag extractor; 409. a second flue gas combustion chamber; FK1, main pipe of air draft; FK4, primary air control device; FK5. Secondary air control means;

fig. 3 is an isometric view of the wind control device of the present invention;

FIG. 4 is an isometric view of a primary air control device;

FIG. 5 is an exploded view of the primary air outlet control pipeline;

FIG. 6 is a schematic structural view of the primary air outlet control pipeline during operation;

FIG. 7 is a sectional view of the primary air outlet control pipeline during operation;

FIG. 8 is an isometric view of the overfire air control apparatus in operation;

FIG. 9 is a schematic view of the control logic of the wind control device of the present invention in a small-sized modularized multi-garbage co-processing system;

in FIGS. 3-9: FK1, main pipe of air draft; FK2, primary air draft branch pipe; FK3. Secondary air draft branch pipe;

FK4, primary air control device; fk41 primary air blower; FK42, primary air outlet bent pipe; FK43, primary air outlet control pipeline; FK431, a primary air outlet pipe section; FK432. Air outlet wind screen switch; fk4321. Inner frame; fk4322. Outer frame body; fk4323. Slide block; FK433, an air outlet wind screen switch support frame; fk434. Drive motor; FK435. An air outlet; fk436. Slider rail;

FK5. Secondary air control means; fk51. Secondary air fan; FK52, secondary air outlet bent pipe; fk53. Secondary air annular line; fk54. Air outlet nozzle.

Detailed Description

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

Example 1

A small-sized modularized multi-garbage cooperative processing system is shown in figure 1 and comprises a central control module 1, a mobile power generation set module 2, a feeding pretreatment module 3, an incineration processing module 4, a flue gas waste heat utilization module 5, a flue gas purification module 6, a sewage treatment module 7, a system coupling customization module 8 and a loading movement module 9, wherein the wind control device is positioned in the incineration processing module 4, and the feeding pretreatment module 3 is associated with the wind control device.

As shown in fig. 2 and 3, the incineration module 4 is provided with an incinerator grate device 406 and a flue gas secondary combustion chamber 409, the bottom of the incinerator grate device 406 is provided with a plurality of ash falling hoppers 407, and the air control device is positioned at the rear end of the incinerator grate device 406 and comprises a primary air control device FK4, a secondary air control device FK5, an air draft main pipe FK1, a primary air draft branch pipe FK2, a secondary air draft branch pipe FK3, a primary air draft connecting pipe section L01, a secondary air draft connecting pipe section L01 and a secondary air draft opening 303; the primary air control device FK4 is arranged in the ash falling hopper 407, and the secondary air control device FK5 is erected on the flue gas secondary combustion chamber 409; two ends of the primary air draft connecting pipe section L01 and the secondary air draft connecting pipe section L01 are respectively connected to a primary air draft opening 303, a secondary air draft opening 303 and an air draft main pipe FK1; the primary air suction opening 303 and the secondary air suction opening 303 are positioned inside the feeding pretreatment module 3; the air draft main pipe FK1 is respectively connected with a primary air draft branch pipe FK2 and a secondary air draft branch pipe FK3; the primary air draft branch FK2 is connected to the primary air control device FK4, and the secondary air draft branch FK3 is connected to the secondary air control device FK5.

The pipe diameter of the ventilation main pipe FK1, the primary air ventilation branch pipe FK2 and the secondary air ventilation branch pipe FK3 does not have special requirements, and the specific pipe diameter can be calculated and determined according to actual requirements.

As shown in fig. 4, the primary air control device FK4 includes a primary air outlet control pipeline FK43, a primary air outlet elbow FK42 and a primary air blower FK41; the number of the primary air outlet control pipelines FK43 is the same as that of the ash falling hopper 407, and the number of the primary air outlet bent pipes FK42 is the same as that of the primary fans FK41 and is half of that of the primary air outlet control pipelines FK 43; the plurality of primary air outlet control pipelines FK43 are respectively arranged in the plurality of ash hoppers 407 in parallel, and two adjacent primary air outlet control pipelines FK43 are connected in series and connected to an air outlet of a primary fan FK41 through a primary air outlet bent pipe FK 42; and an air inlet of the primary fan FK41 is connected with the primary air exhausting branch pipe FK2.

In a preferred embodiment, the number of the first ventilation branch FK2 is the same as the number of the first ventilation fans FK41, and each first ventilation branch FK2 corresponds to one first ventilation fan FK41.

As shown in fig. 5 to 7, the primary air outlet control circuit FK43 includes a primary air outlet pipe section FK431, an air outlet wind shielding switch FK432, and a driving motor FK434; two rows of air outlets FK435 are uniformly arranged at the middle section part of the primary air outlet pipe section FK431, and the two rows of air outlets FK435 are symmetrically arranged at two sides of the primary air outlet pipe section FK 431; a plurality of sliding block rails FK436 are arranged between two adjacent air outlets FK435 and at two ends of a primary air outlet pipe section FK431, and a plurality of air outlet wind-shielding switch supporting frames FK433 are arranged on the circumferential direction where the sliding block rails FK436 are located.

As shown in fig. 5 to 7, the air outlet wind shielding switch FK432 includes an inner frame FK4321, an outer frame FK4322, and a slider FK4323, and the inner frame FK4321 and the outer frame FK4322 are fixedly connected by the slider FK 4323; the sliding block FK4323 is clamped in the sliding block track FK436 and can move along the sliding block track FK 436; the inner frame body FK4321 is tightly attached to the inner wall of the primary air outlet pipe section FK431, and a transverse plate structure for shielding the air outlet FK435 is arranged at each air outlet FK435 of the inner frame body FK 4321; the outer frame body FK4322 is a plurality of annular structures, and is erected on the outer wall of the primary air outlet pipe section FK431 through a plurality of air outlet wind-shielding switch supporting frames FK433, wherein outer rings of the annular structures erected at two ends of the primary air outlet pipe section FK431 are arranged into a gear structure (figure 6).

As shown in fig. 5 to 7, the number of the driving motors FK434 is 2, the driving motors FK434 are respectively and fixedly arranged at two ends of the primary air outlet duct section FK431, and the gear structure of the outer frame FK4322 is meshed with the gear of the driving motor FK434; the driving motor FK434 drives the outer frame FK4322 to move through the gear structure, and then drives the whole air outlet wind screen switch FK432 to move along the slider rail FK436.

In a preferred embodiment, the driving motors FK434 are located outside the ash hopper 407 and are arranged symmetrically. The advantages of such a design are as follows: firstly, the driving motor FK434 is arranged outside the ash falling bucket 407, so that the influence of high temperature and ash in the ash falling bucket 407 can be avoided, the service life of the driving motor FK434 can be prolonged, and the maintenance and the overhaul are convenient; secondly, symmetrically arranged, the driving motors FK434 on two sides simultaneously output torque to control the rotation of the air outlet wind shielding switch FK432, and the force is uniform and can be accurately controlled.

As shown in fig. 8, the overfire air control system FK5 includes an overfire air loop FK53, an outlet nozzle FK54, an overfire air outlet elbow FK52 and an overfire air blower FK51; the secondary air annular pipeline FK53 is erected on the outer wall of the pipeline of the flue gas secondary combustion chamber 409 for a circle; a plurality of holes are formed in the periphery of the outer wall of the flue gas secondary combustion chamber 409, a plurality of air outlet nozzles FK54 are arranged on the secondary air annular pipeline FK53, the air outlet nozzles FK54 correspond to the holes one by one, and the end parts of the air outlet nozzles FK54 are inserted into the holes of the flue gas secondary combustion chamber 409; the secondary air annular pipeline FK53 is connected to an air outlet of a secondary air blower FK51 through a secondary air outlet bent pipe FK52, and an air inlet of the secondary air blower FK51 is connected with a secondary air exhaust branch pipe FK3.

The operation process of the wind control device of the small modularized multi-garbage cooperative processing system comprises the following specific steps:

as shown in fig. 2 and 3, the left side of fig. 2 is a feed pretreatment module 3, the right side is an incineration module 4, a primary air control device FK4 supplies air volume required for combustion in the incinerator, and a secondary air control device FK5 supplies air volume required for turbulent air flow in the flue gas secondary combustion chamber 409. The required amount of wind of the wind control device of this embodiment is by one, overgrate air convulsions connecting tube section L01 through one, overgrate air convulsions mouth 303 extraction air in feeding pre-treatment module 3 to through convulsions person in charge FK1 to once wind convulsions branch pipe FK2 and overgrate air convulsions branch pipe FK3 let in air admission primary air control device FK4 and overgrate air control device FK5.

As shown in fig. 4, each ash hopper 407 has a set of primary air outlet control lines FK43, two adjacent primary air outlet control lines FK43 are connected in series, and a set of primary air fans FK41 supplies primary air to two adjacent ash hoppers 407; the driving motors FK434 of each set of primary air outlet control pipeline FK43 are located outside the ash falling hopper 407 and are symmetrically arranged, and the air outlet conditions of the primary air outlet pipeline sections FK431 are controlled together.

As shown in fig. 5 to 7, in the primary air outlet control circuit FK43, the driving motor FK434 can control the rotation of the air outlet wind shielding switch FK432 by the gear structure of the outer frame FK4322 engaged therewith, and the purpose of controlling the primary air outlet amount can be achieved by controlling the plate structure of the inner frame FK4321 to shield the air outlet FK435.

As shown in fig. 8, the overfire air control device FK5 can also adjust the amount of overfire air in the second flue gas combustion chamber 409 by controlling the opening degree of the overfire air blower FK51.

In a preferred embodiment, the air control device described in this embodiment has complete control logic, and further includes an intelligent control system, as shown in fig. 9, the intelligent control system takes an intelligent control terminal as a center, based on a feedback signal of a combustion monitoring system in the incinerator, and the intelligent control terminal is respectively connected to and controls the primary air blower FK41, the secondary air blower FK51, and the driving motor FK434 of each primary air outlet duct section FK431 (there is no special air blower at the primary and secondary air suction ports 303 to draw air, since the primary air blower FK41 and the secondary air blower FK51 are controlled, the total air suction amount is also controlled). The burning situation in the incinerator is identified and captured by a burning monitoring system, and signals are fed back to an intelligent control terminal, the intelligent control terminal judges the air supply amount of primary air and secondary air of each part through processing, and further controls the total air supply amount of a primary air FK41, and simultaneously controls a driving motor FK434 and a secondary air FK51 of a primary air outlet pipe section FK431 in each ash falling hopper 407, so that the primary air and secondary air demand of the incinerator grate corresponding to each ash falling hopper 407 is accurately controlled.

While the embodiments of the present invention have been described in detail with reference to the drawings, the specific configurations are not limited to the embodiments, and may include design changes and the like within a range not departing from the gist of the present invention.

Claims (5)

1. A wind control device of a small-sized modularized multi-garbage co-processing system comprises a feeding pre-processing module and an incineration processing module of the small-sized modularized multi-garbage co-processing system, wherein the incineration processing module comprises an incinerator grate device and a flue gas secondary combustion chamber, the bottom of the incinerator grate device is provided with a plurality of ash falling hoppers, and the wind control device is positioned at the rear end of the incinerator grate device and is characterized in that the wind control device comprises a primary wind control device, a secondary wind control device, a main draft pipe, a primary wind draft branch pipe, a secondary wind draft branch pipe, a primary wind draft connecting pipe section, a secondary wind draft connecting pipe section, a primary wind draft port and a secondary wind draft port; the primary air control device is arranged in the ash falling hopper, and the secondary air control device is erected on the flue gas secondary combustion chamber; two ends of the primary air draft connecting pipe section and the secondary air draft connecting pipe section are respectively connected to a primary air draft opening, a secondary air draft opening and an air draft main pipe; the primary air suction opening and the secondary air suction opening are positioned inside the feeding pretreatment module; the main draft pipe is respectively connected with a primary air draft branch pipe and a secondary air draft branch pipe; the primary air exhaust branch pipe is connected to the primary air control device, and the secondary air exhaust branch pipe is connected to the secondary air control device;

the primary air control device comprises a primary air outlet control pipeline, a primary air outlet bent pipe and a primary fan; the number of the primary air outlet control pipelines is the same as that of the ash falling buckets, and the number of the primary air outlet bent pipes is the same as that of the primary fans and is half of that of the primary air outlet control pipelines; the primary air outlet control pipelines are respectively arranged in parallel in the ash falling hoppers, and two adjacent primary air outlet control pipelines are connected in series and connected to an air outlet of a primary fan through a primary air outlet bent pipe; an air inlet of the primary fan is connected with a primary air exhaust branch pipe;

the secondary air control device comprises a secondary air annular pipeline, an air outlet nozzle, a secondary air outlet bent pipe and a secondary fan; the secondary air annular pipeline is erected on the outer wall of the pipeline of the flue gas secondary combustion chamber for a circle; a plurality of holes are formed in the periphery of the outer wall of the pipeline of the flue gas secondary combustion chamber, a plurality of air outlet nozzles are arranged on the secondary air annular pipeline, the plurality of air outlet nozzles are in one-to-one correspondence with the plurality of holes, and the end parts of the air outlet nozzles are inserted into the holes; the secondary air annular pipeline is connected to an air outlet of the secondary air fan through a secondary air outlet bent pipe, and an air inlet of the secondary air fan is connected with a secondary air exhaust branch pipe.

2. The wind control device of a small-scale modular multiple waste co-processing system according to claim 1, wherein the primary air outlet control pipeline comprises a primary air outlet pipe section, an air outlet wind screen switch and a driving motor; two rows of air outlets are uniformly arranged at the middle section part of the primary air outlet pipe section, and the two rows of air outlets are symmetrically arranged at two sides of the primary air outlet pipe section; a plurality of sliding block rails are arranged between two adjacent air outlets and at two ends of the primary air outlet pipe section, and a plurality of air outlet wind-shielding switch support frames are arranged on the circumference where the sliding block rails are located; the air outlet wind switch comprises an inner frame body, an outer frame body and a sliding block, wherein the inner frame body is fixedly connected with the outer frame body through the sliding block; the sliding block is arranged in the sliding block track and can move along the sliding block track; the inner frame body is tightly attached to the inner wall of the primary air outlet pipe section, and a transverse plate structure is arranged at each air outlet of the inner frame body and used for shielding the air outlet; the outer frame body is of a plurality of annular structures, and is erected on the outer wall of the primary air outlet pipe section through a plurality of air outlet wind-shielding switch support frames, wherein the outer rings of the annular structures erected at two ends of the primary air outlet pipe section are arranged into gear structures; the number of the driving motors is 2, the driving motors are respectively and fixedly arranged at two ends of the primary air outlet pipe section, and the gear structures are meshed with gears of the driving motors; the driving motor drives the outer frame body to move through the gear structure, and then drives the whole air outlet wind shielding switch to move along the sliding block track.

3. The wind control device of a small modular multiple waste co-processing system as claimed in claim 2, wherein the driving motors are located outside the ash hopper and are symmetrically arranged.

4. The wind control device of a small-scale modular multi-garbage co-processing system as claimed in claim 1, wherein the number of the branch primary air draft pipes is the same as the number of the primary air blowers, and each branch primary air draft pipe corresponds to one primary air blower.

5. The air control device of a small-scale modularized multi-waste cooperative processing system according to any one of claims 1-4, further comprising an intelligent control system, wherein the intelligent control system is centered on an intelligent control terminal and based on a feedback signal of a combustion monitoring system in the incinerator, and the intelligent control terminal is respectively connected with and controls a primary air fan, a secondary air fan and a driving motor of each primary air outlet pipe section.

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