CN115338231A - Overwater garbage treatment system and method - Google Patents

Abstract

The invention belongs to the field of garbage treatment, and particularly relates to a water garbage treatment system which comprises a transmission cylinder, wherein a feed inlet is formed in the right side of the transmission cylinder, a conveying screw rod is rotatably connected in the transmission cylinder, a plurality of water outlets are formed in the lower end of the transmission cylinder, a pressure bearing cover is fixedly connected to the upper end of the transmission cylinder, the upper end of the conveying screw rod is rotatably connected with the pressure bearing cover, a compression cylinder is slidably connected on the transmission cylinder, a slide rod is slidably connected in the compression cylinder, a pressing plate is fixedly connected at the lower end of the slide rod, a spring is fixedly connected between the inner wall of the transmission cylinder and the pressing plate, two first cylinders are fixedly connected on the transmission cylinder, and the compression cylinder is fixedly connected to the moving ends of the two first cylinders.

Description

Overwater garbage treatment system and method

Technical Field

The invention belongs to the field of garbage treatment, and particularly relates to a system and a method for treating garbage on water.

Background

Waste is a solid, fluid substance that is not needed or useful; in large cities with dense population, garbage disposal is a headache problem, and at present, a large amount of floating garbage still exists in lakes, rivers, ports and other places in many areas in China, which causes bad influence on local hydrological environment.

At present, river course rubbish clearance mode still mainly uses the manual driving ship to salvage as leading, but because ship storage space is limited, need frequently carry rubbish, has the problem that inefficiency and intensity of labour are big.

Disclosure of Invention

In view of this, the technical problem to be solved by the present invention is to provide a system and a method for treating aquatic garbage, which can compress river garbage and reduce the occupied space.

The invention provides a water garbage treatment system which comprises a transmission cylinder, wherein a feed inlet is formed in the right side of the transmission cylinder, a transmission screw rod is rotatably connected in the transmission cylinder, a plurality of water outlets are formed in the lower end of the transmission cylinder, a pressure bearing cover is fixedly connected to the upper end of the transmission cylinder, the upper end of the transmission screw rod is rotatably connected with the pressure bearing cover, a compression cylinder is slidably connected onto the transmission cylinder, a slide rod is slidably connected into the compression cylinder, a pressing plate is fixedly connected to the lower end of the slide rod, a spring is fixedly connected between the inner wall of the transmission cylinder and the pressing plate, two first air cylinders are fixedly connected onto the transmission cylinder, and the compression cylinder is fixedly connected to the moving ends of the two first air cylinders.

The lower end of the transmission cylinder is fixedly connected with a first motor, and the conveying screw is fixedly connected to an output shaft of the first motor.

The lower end of the transmission cylinder is fixedly connected with a flow guide cover.

Fixedly connected with feeder hopper on the transmission section of thick bamboo, the feeder hopper is located the feed inlet department on transmission section of thick bamboo right side, and three corner boxes of fixedly connected with on the feeder hopper rotate on three corner boxes and are connected with a plurality of rollers, and the cover has the V belt on a plurality of rollers.

A treatment method of an overwater garbage treatment system is characterized by comprising the following steps:

the method comprises the following steps: the lower end of the conveyor belt is inserted below the horizontal plane of the river channel by adjusting the angle between the conveyor belt and the feed hopper;

step two: conveying river channel garbage to a position between the conveyor belt and the triangular belt through the conveyor belt;

step three: the conveyor belt is matched with the V-belt to crush the river channel garbage;

step four: iron garbage in the river channel garbage is adsorbed and screened out through a triangular belt;

step five: the triangular belt is matched with the feed hopper to convey the river channel garbage into the conveying cylinder;

step six: the conveying cylinder conveys the river channel garbage to the compression cylinder, and the compression cylinder is matched with the compression cylinder to compress the river channel garbage.

Drawings

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

FIGS. 1 and 2 are schematic diagrams showing the overall construction of an aquatic waste disposal system;

FIGS. 3 and 4 are schematic views showing the structure of the conveyor belt;

FIG. 5 is a schematic view of the feed hopper;

FIG. 6 is a schematic structural diagram of a triangular frame;

FIG. 7 is a schematic view of the structure of the transfer drum;

FIG. 8 is a sectional view showing the structure of the transfer cylinder;

FIG. 9 is a schematic structural view of a pressure containment hood;

fig. 10 is a schematic structural view of the gear.

Detailed Description

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

An aquatic refuse disposal system, referring to fig. 5 to 9, is a schematic view showing an embodiment of the present invention capable of compressing river waste to reduce an occupied space, and further,

including a transmission section of thick bamboo 101, the feed inlet has been seted up on transmission section of thick bamboo 101 right side, it is connected with transfer screw 105 to rotate through the bearing in the transmission section of thick bamboo 101, a plurality of outlet 102 have been seted up to transmission section of thick bamboo 101 lower extreme, transmission section of thick bamboo 101 upper end is through bolt fixedly connected with pressure cover 104, transfer screw 105 upper end is connected through the bearing rotation with pressure cover 104, sliding connection has a compression section of thick bamboo 201 on the transmission section of thick bamboo 101, sliding connection has slide bar 203 in the compression section of thick bamboo 201, be used for coordinating the gliding hole of slide bar 203 to be offered on the compression section of thick bamboo 201, slide bar 203 lower extreme passes through bolt fixedly connected with clamp plate 202, welded fastening is connected with spring 204 between transmission section of thick bamboo 101 inner wall and the clamp plate 202, pass through two first cylinders 205 of bolt fixedly connected with on the transmission section of thick bamboo 101, compression section of thick bamboo 201 passes through the removal end of bolt fixed connection at two first cylinders 205.

Firstly add the river course rubbish of collecting to transmission cylinder 101 from the feed inlet on transmission cylinder 101 right side in, then control transfer screw 105 and rotate, transfer screw 105 can upwards convey the river course rubbish in the transmission cylinder 101 when rotating, river course rubbish gets into in the compression section of thick bamboo 201 through the gap between transmission cylinder 101 and the pressure-bearing cover 104, rubbish when progressively increasing in the compression section of thick bamboo 201, the removal end shrink of two controllable first cylinders 205 of staff, and then drive the downward slip of compression section of thick bamboo 201, make clamp plate 202 press river course rubbish, clamp plate 202 and the cooperation of pressure-bearing cover 104 can play the effect of extrudeing river course rubbish this moment, thereby can reduce the occupation space of river course rubbish in the compression section of thick bamboo 201, can discharge unnecessary water in the river course rubbish simultaneously under the extrusion, discharged water flows into in the transmission cylinder 101, at last from a plurality of outlet 102 automatic discharges.

Make clamp plate 202 have elasticity under the effect of spring 204 and slide bar 203, thereby avoid hard contact to lead to compression section of thick bamboo 201 upper portion to warp, the removal end of two first cylinders 205 stretches out makes compression section of thick bamboo 201 reset after the extrusion is accomplished, clamp plate 202 resets under the elastic action of spring 204, when transmission section of thick bamboo 101 continues upwards to transmit river course rubbish, river course rubbish can be with the rubbish jack-up of compressed before, continue to transmit river course rubbish in the compression section of thick bamboo 201, thereby reach the purpose of extension compression section of thick bamboo 201 save time, the removal end of two first cylinders 205 of final control stretches out, make compression section of thick bamboo 201 break away from transmission section of thick bamboo 101, thereby be convenient for take out the rubbish piece of compressed.

Referring to fig. 2 and 8, there is shown a schematic view of an embodiment of the invention capable of driving, and further,

the lower end of the transmission cylinder 101 is fixedly connected with a first motor 106 through a bolt, and the transmission screw 105 is fixedly connected to an output shaft of the first motor 106 through a coupler.

When the first motor 106 is started, the first motor 106 drives the conveying screw 105 to rotate, so that the function of conveying the garbage is realized.

Referring to fig. 9, there is shown a schematic view of an embodiment capable of guiding the flow of extrusion-discharged water according to the present invention, and further,

the lower end of the transmission cylinder 101 is fixedly connected with a flow guide cover 103 in a welding manner.

The diversion cover 103 is used for diversion of water discharged by extrusion, and influence on the first motor 106 is avoided.

Referring to fig. 5-6, there is shown a schematic view of an embodiment of the present invention capable of transferring the river waste in the feed hopper 301 into the transport cylinder 101, and further,

through bolt fixedly connected with feeder hopper 301 on the transmission section of thick bamboo 101, feeder hopper 301 is located the feed inlet department on transmission section of thick bamboo 101 right side, through bolt fixedly connected with triangle frame 302 on feeder hopper 301, is connected with a plurality of rollers through the bearing rotation on the triangle frame 302, and the cover has V-belt 303 on a plurality of rollers.

The staff puts into feeder hopper 301 with river course rubbish in, then control V-belt 303 clockwise rotation, and V-belt 303 bottom and river course rubbish produce the friction to can convey the river course rubbish in the feeder hopper 301 to transmission section of thick bamboo 101 in.

Referring to fig. 5-6, schematic diagrams illustrating an embodiment of the present invention capable of absorbing iron-based garbage in river garbage are shown, and further,

a plurality of magnet strips 304 are fixedly connected to the triangular belt 303 through bolts, and a baffle 306 is fixedly connected to the upper end of the triangular frame 302 through bolts.

When the V-belt 303 conveys river course rubbish, a plurality of magnet strips 304 on the V-belt 303 can adsorb the iron rubbish in the river course rubbish, such as iron can and can box to the realization is to rubbish cyclic utilization's purpose.

The absorbed iron garbage is conveyed upwards through the triangular belt 303 and finally blocked by the baffle 306, and the iron garbage is finally collected at the gap between the triangular belt 303 and the conveying drum 101.

Referring to fig. 6, there is shown a schematic view of an embodiment of the present invention that functions to increase the friction between the v-belt 303 and the river waste, and further,

a plurality of projections 305 are fixedly connected to each magnet bar 304 by bolts.

A plurality of lugs 305 play the effect of increasing frictional force between V-belt 303 and the river course rubbish, are convenient for convey the river course rubbish, offer a plurality of notches that are used for through lug 305 on the baffle 306.

Referring to fig. 1-4, there are shown schematic diagrams of embodiments of the present invention that can perform the function of collecting debris on the surface of a river, and further,

feed hopper 301 is last to rotate through the bearing and is connected with two backplate 401, rotates through the bearing in the middle of two backplate 401 and is connected with two transfer rollers, and the cover has conveyer belt 402 on two transfer rollers, and feed hopper 301 lower extreme articulates the second cylinder 405 that has through the axle, and two backplate 401 lower extremes pass through the axle and articulate the removal end at second cylinder 405.

The staff is flexible through the removal end of control second cylinder 405, and second cylinder 405 drives two backplate 401 and rotates on feeder hopper 301, thereby can change the angle between conveyer belt 402 and the feeder hopper 301, thereby make conveyer belt 402 lower extreme can insert below the river course horizontal plane, then control conveyer belt 402 anticlockwise rotation, and then can upwards convey the rubbish that floats on the surface of water, get into feeder hopper 301 at last in, the realization is to the function that rubbish was collected on the river course surface of water.

Referring to fig. 3-4, there is shown a schematic view of an embodiment of the present invention capable of crushing a relatively large volume of waste, and further,

the conveyor belt 402 is provided with a plurality of water leakage grooves 403, and the conveyor belt 402 is fixedly connected with a plurality of matching convex blocks 404 through bolts.

A plurality of water leakage grooves 403 are used for draining redundant water in the river course rubbish that conveys on the conveyer belt 402 to alleviate the weight of river course rubbish, conveyer belt 402 drives a plurality of cooperation lugs 404 when in operation and removes, and a plurality of cooperation lugs 404 can cooperate with a plurality of lugs 305, thereby can pulverize the great rubbish of volume, for example iron can and branch, thereby reduce occupation space, the subsequent compression of being convenient for is handled.

Referring to fig. 1, there is shown an intent of an embodiment in accordance with the present invention to facilitate simultaneous conveyance and screening of river waste, and further,

a second motor 501 is fixedly connected to the feed hopper 301 through bolts, gears 502 are fixedly connected to one of the rollers on the triangular frame 302 and one of the conveying rollers on the two guard plates 401 through keys, the two gears 502 are in meshing transmission, and one of the gears 502 is fixedly connected to an output shaft of the second motor 501 through a coupler.

Start second motor 501, second motor 501 drives two gear 502 meshing transmissions to drive V-belt 303 and conveyer belt 402 operation, realize V-belt 303 and conveyer belt 402 synchro control, be convenient for transmit river course rubbish and filter simultaneously.

A treatment method of an overwater garbage treatment system is characterized by comprising the following steps:

the method comprises the following steps: the lower end of the conveyor belt 402 is inserted below the river level by adjusting the angle between the conveyor belt 402 and the feed hopper 301;

step two: river waste is conveyed between the conveyor belt 402 and the V-belt 303 through the conveyor belt 402;

step three: the conveyor belt 402 is matched with the V-belt 303 to crush the river waste;

step four: iron garbage in the river channel garbage is adsorbed and screened out through a triangular belt 303;

step five: the triangular belt 303 is matched with the feed hopper 301 to convey the river channel garbage into the conveying cylinder 101;

step six: the conveying cylinder 101 conveys the river channel garbage into the compression cylinder 201, and the compression cylinder 201 is matched to compress the river channel garbage.

Claims (10)

1. The utility model provides a refuse treatment system on water which characterized in that: including a transmission section of thick bamboo (101), the feed inlet has been seted up on a transmission section of thick bamboo (101) right side, the internal rotation of a transmission section of thick bamboo (101) is connected with transfer screw (105), a plurality of outlet (102) have been seted up to a transmission section of thick bamboo (101) lower extreme, transmission section of thick bamboo (101) upper end fixedly connected with bears pressure cover (104), transfer screw (105) upper end is rotated with pressure cover (104) and is connected, sliding connection has a compression section of thick bamboo (201) on a transmission section of thick bamboo (101), sliding connection has slide bar (203) in compression section of thick bamboo (201), slide bar (203) lower extreme fixedly connected with clamp plate (202), the fixed practice is connected with spring (204) between transmission section of thick bamboo (101) inner wall and clamp plate (202), two first cylinders (205) of fixedly connected with on a transmission section of thick bamboo (101), compression section of thick bamboo (201) fixed connection is held in the removal of two first cylinders (205).

2. An aquatic refuse disposal system according to claim 1, wherein: the lower end of the transmission cylinder (101) is fixedly connected with a first motor (106), and the conveying screw rod (105) is fixedly connected to an output shaft of the first motor (106).

3. An aquatic refuse treatment system according to claim 2, wherein: the lower end of the transmission cylinder (101) is fixedly connected with a flow guide cover (103).

4. An aquatic refuse disposal system according to claim 1, wherein: fixedly connected with feeder hopper (301) on transmission section of thick bamboo (101), feeder hopper (301) are located the feed inlet department on transmission section of thick bamboo (101) right side, and fixedly connected with triangle frame (302) is gone up in feeder hopper (301), and it is connected with a plurality of rollers to rotate on triangle frame (302), and the cover has V-belt (303) on a plurality of rollers.

5. An aquatic refuse treatment system according to claim 4, wherein: the triangular belt (303) is fixedly connected with a plurality of magnet strips (304), and the upper end of the triangular frame (302) is fixedly connected with a baffle (306).

6. An aquatic refuse treatment system according to claim 5, wherein: each magnet strip (304) is fixedly connected with a plurality of protruding blocks (305).

7. An aquatic refuse treatment system according to claim 4, wherein: rotation is connected with two backplate (401) on feeder hopper (301), and rotation is connected with two transfer rollers in the middle of two backplate (401), and the cover has conveyer belt (402) on two transfer rollers, and feeder hopper (301) lower extreme articulated second cylinder (405) that have, two backplate (401) lower extremes articulate the removal end at second cylinder (405).

8. An aquatic refuse treatment system according to claim 2, wherein: a plurality of water leakage grooves (403) are formed in the conveyor belt (402), and a plurality of matching convex blocks (404) are fixedly connected to the conveyor belt (402).

9. The aquatic refuse treatment system according to claim 8, wherein: the feeding hopper (301) is fixedly connected with a second motor (501), one of the rollers on the triangular frame (302) and one of the conveying rollers on the two guard plates (401) are fixedly connected with gears (502), the two gears (502) are in meshing transmission, and one of the gears (502) is fixedly connected to an output shaft of the second motor (501).

10. A method of treatment for use in an aquatic refuse treatment system according to claim 9, comprising the steps of:

the method comprises the following steps: the lower end of the conveyor belt (402) is inserted below the river level by adjusting the angle between the conveyor belt (402) and the feed hopper (301);

step two: conveying river waste between the conveyor belt (402) and the triangular belt (303) through the conveyor belt (402);

step three: the conveyor belt (402) is matched with the triangular belt (303) to crush the river waste;

step four: iron garbage in the river channel garbage is adsorbed and screened out through a triangular belt (303);

step five: the triangular belt (303) is matched with the feed hopper (301) to convey the river channel garbage into the conveying cylinder (101);

step six: the conveying cylinder (101) conveys the river channel garbage into the compression cylinder (201), and the compression cylinder (201) is matched to compress the river channel garbage.

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