CN210700276U - Crusher for recycling water surface garbage pollutants - Google Patents

Abstract

The utility model relates to the technical field of environmental protection equipment, and discloses a crusher for recycling water surface garbage pollutants, which comprises a salvage conveyor, wherein the salvage conveyor is arranged obliquely, the position of a machine head of the salvage conveyor is lower than that of a machine tail, the machine tail of the salvage conveyor is provided with a material receiving bin, a fracturing mechanism is arranged in the material receiving bin, and a rolling mechanism is arranged below the fracturing mechanism; a shredding mechanism is arranged below the rolling mechanism, a water-containing separation bin is arranged below the shredding mechanism, a floating opening is arranged on the side wall surface of the water-containing separation bin, and a plastic collecting tank is arranged outside the floating opening; a mixing conveyor is arranged at the lower part of the water-containing separation bin, and a glass collecting tank is arranged at the tail of the mixing conveyor; a ferromagnetic conveyor is arranged above the mixing conveyor, and a ferromagnetic collecting tank is arranged at the tail of the ferromagnetic conveyor. The utility model discloses simple structure, work efficiency is high, can realize the classification and the recovery processing of rubbish fast, greatly reduced artifical intensity of labour.

Description

Crusher for recycling water surface garbage pollutants

Technical Field

The utility model relates to an environmental protection equipment technical field, concretely relates to surface of water rubbish pollutant recycle's breaker.

Background

The water environment is an ecological environment related to people's life relatives, and the water body is an indispensable component for maintaining ecological balance by abundant animals, plants, microorganisms, mineral substances and the like. The health condition of the water environment directly influences the living and living states of people.

The main composition of the water environment is a water body, the ecological balance in the water body is always maintained in a dynamic balance state, and when people excessively participate in the ecological environment of the water body, the ecological balance of the water body is damaged. For example, a large amount of municipal waste, industrial waste and the like are dumped and discharged into a water body, so that the waste in the water body is deposited, the waste floating on the water surface is more and cannot be effectively cleaned, the content of various chemical elements in the water body is seriously influenced, the living structures of animals, plants and microorganisms in the water body are influenced, and the water body is damaged. The current method of dealing with surface of water floating garbage is to carry out artifical salvage, and artifical salvage intensity of labour is big, and efficiency is not high and have certain danger, and the rubbish of artifical salvage mixes together, still need classify once more and just can obtain effective processing, and the process of reclassification is through artificial realization wantonly, so the processing procedure of surface of water rubbish under is too loaded down with trivial details, and is inefficient, and the cost is high.

Therefore, the existing water surface garbage treatment mode cannot rapidly realize the classification treatment of garbage, the dependence on manual assistance is high, and the treatment result cannot meet the increasing requirements. Therefore, a more reasonable technical scheme is required to be provided to solve the technical problems in the prior art.

SUMMERY OF THE UTILITY MODEL

The utility model provides a surface of water rubbish pollutant recycle's breaker aims at salvaging and categorizing the plastic refuse, glass rubbish, the metal waste of the surface of water through automation equipment to timely broken handle has improved surface of water rubbish recovery processing's efficiency and reliability.

In order to realize the above effect, the utility model discloses the technical scheme who adopts does:

a crusher for recycling water surface garbage pollutants comprises a salvaging conveyor, wherein the salvaging conveyor is obliquely arranged, the position of a machine head of the salvaging conveyor is lower than that of a machine tail, a material receiving bin is arranged at the machine tail of the salvaging conveyor, a fracturing mechanism is arranged in the material receiving bin, and a rolling mechanism is arranged below the fracturing mechanism; a shredding mechanism is arranged below the rolling mechanism, a water-containing separation bin is arranged below the shredding mechanism, a floating opening is arranged on the side wall surface of the water-containing separation bin, and a plastic collecting tank is arranged outside the floating opening; a mixing conveyor is arranged at the lower part of the water-containing separation bin, and a glass collecting tank is arranged at the tail of the mixing conveyor; a ferromagnetic conveyor is arranged above the mixing conveyor, and a ferromagnetic collecting tank is arranged at the tail of the ferromagnetic conveyor.

Further, the fracturing mechanism disclosed in the above technical solution is optimized, and the following feasible technical solutions are provided: the fracturing mechanism comprises a fixed jaw plate and a movable jaw plate, the fixed jaw plate is close to the lower end of the movable jaw plate, and a rotating shaft is arranged at the lower end of the movable jaw plate; the upper end of the movable jaw plate is provided with a secondary connecting rod, the secondary connecting rod is connected with the movable jaw plate and a driving motor, and the driving motor drives the movable jaw plate to be close to and far away from the fixed jaw plate through the secondary connecting rod.

Further, the rolling mechanism disclosed in the above technical solution is optimized, and the following feasible technical solutions are provided: the rolling mechanism comprises a main roll shaft and an auxiliary roll shaft, wherein gears which are meshed with each other are arranged on the main roll shaft and the auxiliary roll shaft.

Further, the rolling mechanism disclosed in the above technical solution is optimized, and the following feasible technical solutions are provided: two adjacent gear tooth footpaths on the primary roll axle are different, and the gear on the secondary roll axle corresponds the setting with the gear on the primary roll axle.

Further, the shredding mechanism disclosed in the above technical solution is optimized, and the following feasible technical solutions are provided: the chopping mechanism comprises a chopping cage, the upper part of the chopping cage is provided with an opening, the lower part of the chopping cage is provided with a screen, a plurality of radial clapboards are arranged in the chopping cage, and knife edge seams are arranged on the clapboards; a main shaft is longitudinally arranged in the cutting cage, a plurality of layers of blades are arranged on the main shaft, and the blades are driven to rotate and penetrate through the knife edge seam when the main shaft rotates; the shredding mechanism further comprises a main shaft motor, and the main shaft motor is arranged outside the material receiving bin and drives the main shaft to rotate through a transmission belt or a transmission chain.

Further, the water separation bin disclosed in the above technical scheme is optimized, and the following feasible technical scheme is given as follows: the water-containing separation bin is of a U-shaped structure, a water inlet is formed in the water-containing separation bin, and water is continuously injected into the water-containing separation bin through the water inlet; the floating opening is arranged at the vertical section of the water separation bin, the separating nozzle is arranged at the floating opening, and water and floating objects flowing out of the separating nozzle fall into the plastic collecting tank.

Further, the hybrid conveyor disclosed in the above technical solution is optimized, and the following feasible technical solutions are provided: the mixing conveyor is arranged at the horizontal section of the water-containing separation bin, the mixing conveyor adopts a metal mesh belt to convey falling sediments, the glass collecting tank is arranged below the tail of the mixing conveyor, and the sediments falling from the mixing conveyor fall into the glass collecting tank.

Further, the ferromagnetic conveyor disclosed in the above technical solution is optimized, and the following feasible technical solutions are provided: the ferromagnetic conveyor is arranged at the horizontal section of the water-containing separation bin, the ferromagnetic conveyor is provided with rubber conveyer belts, a permanent magnet is arranged between the upper rubber conveyer belt and the lower rubber conveyer belt of the ferromagnetic conveyor, the permanent magnet is arranged along the conveying direction of the ferromagnetic conveyor, the tail of the ferromagnetic conveyor extends to the middle part of the ferromagnetic collecting tank, and the permanent magnet extends to the initial position of the ferromagnetic collecting tank; when setting up like this, carry to ferromagnetic collecting vat along with the conveyer belt as ferromagnetic substance, the adsorption affinity of permanent magnet reduces, and ferromagnetic substance will not be attracted, begins the whereabouts this moment and falls into in the ferromagnetic collecting vat.

Further, the hybrid conveyor and the ferromagnetic conveyor disclosed in the above technical solutions are optimized, and the following feasible technical solutions are provided: the traction motors of the mixing conveyor and the ferromagnetic conveyor are positioned outside the water-containing separation bin, and are respectively connected with the mixing conveyor and the ferromagnetic conveyor through a transmission belt or a transmission chain for transmission.

Further, the plastic collecting tank, the glass collecting tank and the ferromagnetic collecting tank disclosed in the above technical solutions are optimized, and the following feasible technical solutions are provided: the bottom of the plastic collecting tank, the bottom of the glass collecting tank and the bottom of the ferromagnetic collecting tank are all provided with water outlets, and blocking separation nets are arranged above the water outlets.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses a fracturing mechanism, crushing treatment is carried out to the rubbish of collecting to rolling mechanism and shredder mechanism, can break into the tiny particle form with rubbish, and with raw materials separation such as plastics, metal and glass, light plastics will float in the upper portion in moisture separation storehouse, fall to the plastics collecting vat in from floating the opening part, other deposits will fall to the mixing conveyer on, and carry to the glass collecting vat, at this in-process, ferromagnetic substance that ferromagnetic conveyer will mix on the conveyer adsorbs and carries to the ferromagnetic collecting vat, the classification of rubbish has been accomplished. The utility model discloses simple structure, work efficiency is high, can realize the classification and the recovery processing of rubbish fast, greatly reduced artifical intensity of labour.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only show some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is an overall schematic view of a crusher;

FIG. 2 is a schematic diagram of the fracturing mechanism;

FIG. 3 is a schematic structural view of a rolling mechanism

FIG. 4 is a schematic structural view of the shredder mechanism;

fig. 5 is a schematic diagram of the structure of a ferromagnetic conveyor.

In the above drawings, the meaning of each reference numeral is: 1. fishing the conveyor; 2. a material receiving bin; 3. a fracturing mechanism; 301. fixing a jaw plate; 302. a movable jaw plate; 303. a secondary connecting rod; 304. a rotating shaft; 305. a drive motor; 4. a rolling mechanism; 401. a primary roller shaft; 402. a secondary roll shaft; 403. a gear; 5. a shredding mechanism; 501. cutting a cage; 502. a partition plate; 503. cutting edge seam; 504. a blade; 505. screening a screen; 506. a main shaft; 507. a spindle motor; 6. a moisture separation bin; 7. a floating opening; 8. a plastic collecting tank; 9. blocking the separation net; 10. a mixing conveyor; 11. a ferromagnetic conveyor; 12. a water outlet; 13. a glass collection tank; 14. a ferromagnetic collection tank; 15. a traction motor; 16. and a permanent magnet.

Detailed Description

The present invention will be further explained with reference to the drawings and the embodiments.

It should be noted that the description of the embodiments is provided to help understanding of the present invention, but the present invention is not limited thereto. Specific structural and functional details disclosed herein are merely illustrative of example embodiments of the invention. The present invention may, however, be embodied in many alternate forms and should not be construed as limited to the embodiments set forth herein.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments of the invention. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms "comprises," "comprising," "includes," and/or "including," when used herein, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, numbers, steps, operations, elements, components, and/or groups thereof.

It should also be noted that, in some alternative implementations, the functions/acts noted may occur out of the order noted in the figures. For example, two figures shown in succession may, in fact, be executed substantially concurrently, or the figures may sometimes be executed in the reverse order, depending upon the functionality/acts involved.

In the following description, specific details are provided to facilitate a thorough understanding of example embodiments. However, it will be understood by those of ordinary skill in the art that the example embodiments may be practiced without these specific details. For example, systems may be shown in block diagrams in order not to obscure the examples in unnecessary detail. In other instances, well-known processes, structures and techniques may be shown without unnecessary detail in order to avoid obscuring example embodiments.

Examples

As shown in fig. 1 to 5, a crusher for recycling water surface garbage pollutants comprises a salvage conveyor 1, wherein the salvage conveyor 1 is obliquely arranged, the head of the salvage conveyor 1 is lower than the tail of the crusher, a receiving bin 2 is arranged at the tail of the salvage conveyor 1, a fracturing mechanism 3 is arranged in the receiving bin 2, and a rolling mechanism 4 is arranged below the fracturing mechanism; a shredding mechanism 5 is arranged below the rolling mechanism 4, a water-containing separation bin 6 is arranged below the shredding mechanism 5, a floating opening 7 is arranged on the side wall surface of the water-containing separation bin 6, and a plastic collecting tank 8 is arranged outside the floating opening 7; a mixing conveyor 10 is arranged at the lower part of the moisture separation bin 6, and a glass collecting tank 13 is arranged at the tail of the mixing conveyor 10; a ferromagnetic conveyor 11 is arranged above the mixing conveyor 10, and a ferromagnetic collecting tank 14 is arranged at the tail of the ferromagnetic conveyor 11.

The fracturing mechanism 3 disclosed in the above technical solution is optimized, and the following feasible technical solutions are given: the fracturing mechanism 3 comprises a fixed jaw plate 301 and a movable jaw plate 302, the fixed jaw plate 301 is close to the lower end of the movable jaw plate 302, and the lower end of the movable jaw plate 302 is provided with a rotating shaft 304; the upper end of the movable jaw 302 is provided with a secondary connecting rod 303, the secondary connecting rod 303 connects the movable jaw 302 and a driving motor 305, and the driving motor 305 drives the movable jaw 302 to approach and depart from the fixed jaw 301 through the secondary connecting rod 303.

The rolling mechanism 4 disclosed in the above technical solution is optimized, and the following feasible technical solutions are provided: the rolling mechanism 4 comprises a primary roller shaft 401 and a secondary roller shaft 402, and the primary roller shaft 401 and the secondary roller shaft 402 are provided with gears 403 which are meshed with each other.

The rolling mechanism 4 disclosed in the above technical solution is optimized, and the following feasible technical solutions are provided: the adjacent two gears 403 on the main roller shaft 401 have different tooth diameters, and the gear 403 on the auxiliary roller shaft 402 is arranged corresponding to the gear 403 on the main roller shaft 401.

The shredder mechanism 5 disclosed in the above technical solution is optimized, and the following feasible technical solutions are provided: the chopping mechanism 5 comprises a cutting cage 501, the upper part of the cutting cage 501 is provided with an opening, the lower part of the cutting cage 501 is provided with a screen 505, a plurality of radial clapboards 502 are arranged in the cutting cage 501, and knife edge slits 503 are arranged on the clapboards 502; a main shaft 506 is longitudinally arranged in the cutting cage 501, a plurality of layers of blades 504 are arranged on the main shaft 506, the blades 504 are driven to rotate when the main shaft 506 rotates, and the blades 504 penetrate through the knife edge gaps 503; the shredding mechanism 5 further includes a spindle motor 507, and the spindle motor 507 is disposed outside the bin 2 and drives the spindle 506 to rotate through a belt or a chain.

The water separation bin 6 disclosed in the above technical scheme is optimized, and the following feasible technical scheme is given as follows: the water separation bin 6 is of a U-shaped structure, a water inlet is formed in the water separation bin 6, and water is continuously injected into the water separation bin 6 through the water inlet; the floating opening 7 is arranged at the vertical section of the water separation bin 6, a separation nozzle is arranged at the floating opening 7, and water and floating objects flowing out of the separation nozzle fall into the plastic collecting tank 8.

The hybrid conveyor 10 disclosed in the above technical solutions is optimized, and the following possible technical solutions are given: the mixing conveyor 10 is arranged at the horizontal section of the moisture separation bin 6, the mixing conveyor 10 adopts a metal mesh belt to convey falling sediments, the glass collecting tank 13 is arranged below the tail of the mixing conveyor 10, and the sediments falling from the mixing conveyor 10 fall into the glass collecting tank 13.

The ferromagnetic conveyor 11 disclosed in the above technical solutions is optimized, and the following feasible technical solutions are given: the ferromagnetic conveyor 11 is arranged at the horizontal section of the separation bin 6, the ferromagnetic conveyor 11 is provided with rubber conveyer belts, a permanent magnet 16 is arranged between the upper rubber conveyer belt and the lower rubber conveyer belt of the ferromagnetic conveyor 11, the permanent magnet 16 is arranged along the conveying direction of the ferromagnetic conveyor 11, the tail of the ferromagnetic conveyor 11 extends to the middle part of the ferromagnetic collecting tank 14, and the permanent magnet 16 extends to the initial position of the ferromagnetic collecting tank 14; when setting up like this, carry to ferromagnetic collecting vat along with the conveyer belt as ferromagnetic substance, the adsorption affinity of permanent magnet reduces, and ferromagnetic substance will not be attracted, begins the whereabouts this moment and falls into in the ferromagnetic collecting vat.

The hybrid conveyor 10 and the ferromagnetic conveyor 11 disclosed in the above technical solutions are optimized, and the following feasible technical solutions are provided: the traction motor 15 of the mixing conveyor 10 and the ferromagnetic conveyor 11 are positioned outside the water separation bin 6, and the traction motor 15 is respectively connected with the mixing conveyor 10 and the ferromagnetic conveyor 11 for transmission through a transmission belt or a transmission chain.

The plastic collecting tank 8, the glass collecting tank 13 and the ferromagnetic collecting tank 14 disclosed in the above technical solutions are optimized, and the following feasible technical solutions are provided: the bottoms of the plastic collecting tank 8, the glass collecting tank 13 and the ferromagnetic collecting tank 14 are provided with water outlets 12, and blocking and separating nets 9 are arranged above the water outlets 12.

The above embodiments are just examples of the present invention, but the present invention is not limited to the above alternative embodiments, and those skilled in the art can obtain other various embodiments by arbitrarily combining the above embodiments, and any one can obtain other various embodiments by the teaching of the present invention. The above detailed description should not be taken as limiting the scope of the invention, which is defined in the following claims, and which can be used to interpret the claims.

Claims (10)

1. The utility model provides a breaker of surface of water rubbish pollutant recycle which characterized in that: the device comprises a salvaging conveyor (1), wherein the salvaging conveyor (1) is obliquely arranged, the position of a machine head is lower than that of a machine tail, a material receiving bin (2) is arranged at the machine tail of the salvaging conveyor (1), a fracturing mechanism (3) is arranged in the material receiving bin (2), and a rolling mechanism (4) is arranged below the fracturing structure; a chopping mechanism (5) is arranged below the rolling mechanism (4), a water-containing separation bin (6) is arranged below the chopping mechanism (5), a floating opening (7) is arranged on the side wall surface of the water-containing separation bin (6), and a plastic collecting tank (8) is arranged outside the floating opening (7); a mixing conveyor (10) is arranged at the lower part of the water-containing separation bin (6), and a glass collecting tank (13) is arranged at the tail of the mixing conveyor (10); a ferromagnetic conveyor (11) is arranged above the mixing conveyor (10), and a ferromagnetic collecting tank (14) is arranged at the tail of the ferromagnetic conveyor (11).

2. The water surface garbage pollutant recycling crusher of claim 1, characterized in that: the fracturing mechanism (3) comprises a fixed jaw plate (301) and a movable jaw plate (302), the fixed jaw plate (301) is close to the lower end of the movable jaw plate (302), and a rotating shaft (304) is arranged at the lower end of the movable jaw plate (302); the upper end of the movable jaw plate (302) is provided with a secondary connecting rod (303), the secondary connecting rod (303) is connected with the movable jaw plate (302) and a driving motor (305), and the driving motor (305) drives the movable jaw plate (302) to approach and keep away from the fixed jaw plate (301) through the secondary connecting rod (303).

3. The water surface garbage pollutant recycling crusher of claim 1, characterized in that: the rolling mechanism (4) comprises a main roller shaft (401) and an auxiliary roller shaft (402), wherein gears (403) which are meshed with each other are arranged on the main roller shaft (401) and the auxiliary roller shaft (402).

4. The water surface garbage pollutant recycling crusher of claim 3, characterized in that: the adjacent two gears (403) on the main roller shaft (401) have different tooth diameters, and the gear (403) on the auxiliary roller shaft (402) is arranged corresponding to the gear (403) on the main roller shaft (401).

5. The water surface garbage pollutant recycling crusher of claim 1, characterized in that: the chopping mechanism (5) comprises a chopping cage (501), the upper part of the chopping cage (501) is provided with an opening, the lower part of the chopping cage is provided with a screen (505), a plurality of radial clapboards (502) are arranged in the chopping cage (501), and knife edge slits (503) are arranged on the clapboards (502); a main shaft (506) is longitudinally arranged in the cutting cage (501), a plurality of layers of blades (504) are arranged on the main shaft (506), the blades (504) are driven to rotate when the main shaft (506) rotates, and the blades (504) penetrate through the knife edge gap (503); the shredding mechanism (5) further comprises a spindle motor (507), wherein the spindle motor (507) is arranged outside the material receiving bin (2) and drives the spindle (506) to rotate through a transmission belt or a transmission chain.

6. The water surface garbage pollutant recycling crusher of claim 1, characterized in that: the water-containing separation bin (6) is of a U-shaped structure, a water inlet is formed in the water-containing separation bin (6), and water is continuously injected into the water-containing separation bin (6) through the water inlet; the floating opening (7) is arranged at the vertical section of the water-containing separation bin (6), a separation nozzle is arranged at the floating opening (7), and water and floating objects flowing out of the separation nozzle fall into the plastic collection tank (8).

7. The water surface garbage pollutant recycling crusher of claim 6, characterized in that: the mixing conveyor (10) is arranged at the horizontal section of the moisture separation bin (6), the mixing conveyor (10) adopts a metal mesh belt to convey falling sediments, the glass collecting tank (13) is arranged below the tail of the mixing conveyor (10), and the sediments falling from the mixing conveyor (10) fall into the glass collecting tank (13).

8. The water surface garbage pollutant recycling crusher of claim 6, characterized in that: ferromagnetic conveyer (11) set up the horizontal segment in moisture separation storehouse (6), ferromagnetic conveyer (11) adopt and set up rubber conveyor belt, and be provided with permanent magnet (16) between the upper and lower rubber conveyor belt of ferromagnetic conveyer (11), permanent magnet (16) set up along the direction of delivery of ferromagnetic conveyer (11), the tail of ferromagnetic conveyer (11) extends to the middle part of ferromagnetic collecting vat (14), permanent magnet (16) extend to the initial position of ferromagnetic collecting vat (14).

9. The crusher for recycling water surface garbage pollutants according to any one of claims 6 to 8, characterized in that: the traction motors (15) of the mixing conveyor (10) and the ferromagnetic conveyor (11) are positioned outside the water separation bin (6), and the traction motors (15) are respectively connected with the mixing conveyor (10) and the ferromagnetic conveyor (11) through a transmission belt or a transmission chain for transmission.

10. The water surface garbage pollutant recycling crusher of claim 1, characterized in that: the bottom of the plastic collecting tank (8), the bottom of the glass collecting tank (13) and the bottom of the ferromagnetic collecting tank (14) are all provided with a water outlet (12), and a blocking and separating net (9) is arranged above the water outlet (12).

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