CN107138478B - Cleaning device - Google Patents

Abstract

The invention relates to a clearing device, which solves the technical problems of large labor amount, high cost, low efficiency and poor clearing effect of the existing clearing method for scallop cultivation cages and comprises a striking device, wherein the striking device comprises a bracket, a striking belt, a rotating shaft and a connecting rod, the rotating shaft is connected to the bracket, the connecting rod is connected with the rotating shaft, and the striking belt is connected with the connecting rod through a hinge piece; the pressing plate device is fixedly connected with the rotating shaft and provided with a connecting rod inserting hole, and the connecting rod penetrates through the connecting rod inserting hole to be connected with the rotating shaft; the pressing plate device is provided with a pushing part; it can be widely applied to the cleaning treatment of attachments on objects.

Description

Cleaning device

Technical Field

The invention relates to a cleaning device, in particular to a cleaning device.

Background

The scallop is a seashell product eaten by people and cultured in seawater, and has delicious meat quality and rich nutrition. At present, the main mode of scallop cultivation is suspension cage raft cultivation, namely, a raft frame is arranged in a sea area, and scallop seedlings are placed in a cultivation cage hung on the raft frame for cultivation. The cultivation cage is an important apparatus for cultivating scallops, most of the existing cultivation cages are netting layered cultivation cages which comprise a plurality of layered plates and netting arranged at the periphery of the layered plates, two adjacent layered plates and the netting jointly form a suspension cage layer, the layered plates are hard nylon net plates, and the netting is woven by smooth nylon net wires.

In the process of cultivation, a large amount of fouling organisms and silt can be attached to the cultivation cage, the weight of the cultivation cage is increased, the stress of the raft frame is increased, meshes on the cultivation cage are blocked, the concentration of dissolved oxygen and bait in the cultivation cage is reduced, and the normal growth of scallops is influenced.

Therefore, the attachments on the scallop cultivation cage need to be removed. The existing cleaning method is manually carried out, the culture cage is firstly dried together with attached fouling organisms and silt, and then the fouling organisms and the silt on the culture cage are manually and repeatedly flapped until the culture cage is cleaned. Obviously, the existing clearing method has the technical defects of large labor capacity, high cost, low efficiency and poor clearing effect.

Disclosure of Invention

The invention aims to solve the technical problems of large labor amount, high cost, low efficiency and poor removing effect of the existing removing method for the scallop cultivation cage, and provides a removing device with small labor amount, low cost, high efficiency and good removing effect.

The technical scheme of the invention is that the clearing device comprises a striking device, wherein the striking device comprises a support, a striking belt, a rotating shaft and a connecting rod, the rotating shaft is connected to the support, the connecting rod is connected with the rotating shaft, and the striking belt is connected with the connecting rod through a hinge piece;

the pressing plate device is fixedly connected with the rotating shaft and provided with a connecting rod inserting hole, and the connecting rod penetrates through the connecting rod inserting hole to be connected with the rotating shaft; the pressing plate device is provided with a pressing part.

Preferably, the number of hinges is two and are oppositely disposed; each hinged part is connected with one beating belt group; the striking belt is made of rubber; the pressing plate device is provided with a first pushing part and a first pushing part.

Preferably, the device further comprises a driving motor, and the driving motor is connected with the rotating shaft through a transmission mechanism.

Preferably, the removing device further comprises an extruding device, the extruding device comprises a frame, a motor, a first upper pressing roller, a first lower pressing roller, a second upper pressing roller, a second lower pressing roller, an upper driving gear disc, a lower driving gear disc, an upper driven gear disc, a lower driven gear disc, a driving chain, a first driven chain and a fourth driven chain, and the motor is connected with the frame; the first upper pressing roller, the first lower pressing roller, the second upper pressing roller and the second lower pressing roller are respectively provided with a central shaft;

two ends of a central shaft of the first lower pressing roller are respectively connected with the frame through bearing seat assemblies, and two ends of a central shaft of the second lower pressing roller are respectively connected with the frame through bearing seat assemblies; two ends of a central shaft of the first upper pressing roller are connected with the frame through sliding bearing seat assemblies respectively, and two ends of a central shaft of the second upper pressing roller are connected with the frame through sliding bearing seat assemblies respectively; a pressure spring is connected between the sliding bearing seat component and the frame;

the lower driving gear disc is connected with a central shaft of the first lower pressing roller, the upper driving gear disc is connected with a central shaft of the first upper pressing roller, and an output shaft of the motor is connected with a driving gear disc; one end of the driving chain is linked with the driving gear disc, and the other end of the driving chain is linked with the lower driving gear disc; the upper driving gear disc is linked with the driving chain, and the steering directions of the upper driving gear disc and the lower driving gear disc are opposite;

the lower driven gear disc is connected with a central shaft of the first lower pressing roll, a central shaft of the second lower pressing roll is connected with a gear, and the first driven chain is connected between the lower driven gear disc and the gear on the central shaft of the second lower pressing roll;

go up the driven gear dish and the central axis of first last compression roller is connected, and the center pin connection of compression roller has the gear on the second, and fourth driven chain connects between the epaxial gear of center of last driven gear dish and second last compression roller.

Preferably, the extrusion device is connected with a third upper press roll, a third lower press roll, a fourth upper press roll and a fourth lower press roll, the third upper press roll is connected with the second upper press roll through a chain, the fourth upper press roll is connected with the third upper press roll through a chain, the third lower press roll is connected with the second lower press roll through a chain, and the fourth lower press roll is connected with the third lower press roll through a chain.

Preferably, the clearing means further comprises a conveyor means, the striking means being mounted on the conveyor means.

The automatic cleaning machine has the advantages of reasonable structure, realization of automatic operation, labor saving, low cost, high efficiency and better cleaning effect. The invention has wide application and can also be applied to the treatment operation of the attached foreign matters of other products.

Further features and aspects of the present invention will become apparent from the following description of specific embodiments with reference to the accompanying drawings.

Drawings

FIG. 1 is a schematic structural diagram of a pressing device of a scallop cultivation cage;

FIG. 2 is a left side view of the extruding device of the scallop cultivation cage;

FIG. 3 is a schematic diagram of the connection among the compression rollers on the compression device of the scallop cultivation cage;

FIG. 4 is a schematic view of the striking device mounted on a conveyor belt assembly;

FIG. 5 is a top view of the conveyor belt assembly;

FIG. 6 is a schematic view of the construction of the striking device;

FIG. 7 is a schematic view of the connection of the striking belt to the spindle in the striking device;

FIG. 8 is a front view of the platen apparatus;

FIG. 9 is a front view side view of the platen apparatus.

The symbols in the drawings illustrate that:

1. the press roll comprises a frame, 2, supporting legs, 3, a first upper press roll, 4, a first lower press roll, 5, a motor, 6, an upper driven gear disc, 7, a lower driven gear disc, 8, a driving chain, 9, a second upper press roll, 10, a second lower press roll, 11, a third upper press roll, 12, a third lower press roll, 13, a fourth upper press roll, 14, a fourth lower press roll, 15, an upper driving gear disc, 16, a lower driving gear disc, 17, a first driven chain, 18, a second driven chain, 19, a third driven chain, 20, a fourth driven chain, 21, a fifth driven chain, 22, a sixth driven chain, 23, a bearing, 24, a bearing, 25, 26, a sliding bearing seat assembly and 28.

33. The belt conveyor comprises a conveyor belt device, a water tank 34, a waterproof cover 35, a beating device 36, a driving motor 37, a water spray pipe 38, a conveyor belt 3301, a front tension pulley 3302, a belt pressing pulley 3304, a rear tension pulley 3305 and a conveyor belt driving motor 3306; 3601. the pressing device comprises a bracket, 3602 a striking belt, 3603 a pressing plate device, 3604 a hinge piece, 3605 a rotating shaft, 3606 a connecting rod, 3607 a driving wheel, 3608 a connecting rod inserting hole, 3609 a first pressing part, 3610 a second pressing part.

Detailed Description

As shown in fig. 1 to 3, the extruding device for scallop cultivation cage includes a frame 1, a leg 2, a motor 5, a first upper press roll 3, a first lower press roll 4, a second upper press roll 9, a second lower press roll 10, a third upper press roll 11, a third lower press roll 12, a fourth upper press roll 13, a fourth lower press roll 14, an upper driving gear disk 15, a lower driving gear disk 16, an upper driven gear disk 6, a lower driven gear disk 7, a driving chain 8, a first driven chain 17, a second driven chain 18, a third driven chain 19, a fourth driven chain 20, a fifth driven chain 21, and a sixth driven chain 22.

The legs 2 are connected to the frame 1 and the motor 5 is mounted on top of the frame 1.

First upper press roll 3 and first lower press roll 4 constitute an extrusion subassembly, and second upper press roll 9 and second lower press roll 10 constitute a second extrusion subassembly, and third upper press roll 11 and third lower press roll 12 constitute a third extrusion subassembly, and fourth upper press roll 13 and fourth lower press roll 14 constitute a fourth extrusion subassembly. The first upper press roll 3, the first lower press roll 4, the second upper press roll 9, the second lower press roll 10, the third upper press roll 11, the third lower press roll 12, the fourth upper press roll 13 and the fourth lower press roll 14 are respectively provided with a central shaft.

Two ends of the central shaft of the first lower pressing roll 4 are respectively connected with the frame 1 through bearing seat assemblies. Two ends of the central shaft of the second lower press roll 10 are respectively connected with the frame 1 through bearing seat assemblies. Two ends of the central shaft of the third lower press roll 12 are respectively connected with the frame 1 through bearing seat components. The two ends of the central shaft of the fourth lower press roll 14 are respectively connected with the frame 1 through bearing seat assemblies.

The two ends of the central shaft of the first upper press roll 3 are respectively connected with the frame 1 through sliding bearing seat assemblies. Two ends of the central shaft of the second upper press roll 9 are respectively connected with the frame 1 through sliding bearing seat assemblies. The two ends of the central shaft of the third upper press roll 11 are respectively connected with the frame 1 through sliding bearing seat assemblies. The two ends of the central shaft of the fourth upper press roll 13 are respectively connected with the frame 1 through sliding bearing seat assemblies.

The two sides of each sliding bearing seat component are respectively provided with a sliding groove, and the sliding grooves are matched with the guide rails on the frame 1. The sliding bearing seat assembly can slide up and down in the vertical direction.

A compression spring is connected between the top of each sliding bearing block assembly and the frame 1, and as shown in fig. 2, a compression spring 25 is connected between the sliding bearing block assembly 26 and the frame 1. That is to say, two compression springs are connected between the sliding bearing seat assemblies at the two ends of the central shaft of the first upper press roll 3 and the frame 1. Similarly, two pressure springs are connected between the sliding bearing seat assemblies at the two ends of the central shaft on the second upper press roller 9 and the frame 1, two pressure springs are connected between the sliding bearing seat assemblies at the two ends of the central shaft on the third upper press roller 11 and the frame 1, and two pressure springs are connected between the sliding bearing seat assemblies at the two ends of the central shaft on the fourth upper press roller 13 and the frame 1.

The bearing seat assembly comprises a bearing seat and a bearing which are connected together. The bearing 23 in fig. 2 represents the bearing in one of the bearing housing assemblies and the bearing 24 in fig. 2 represents the bearing in one of the sliding bearing housing assemblies.

The lower driving gear disc 16 is connected with the central shaft of the first lower press roll 4, and the upper driving gear disc 15 is connected with the central shaft of the first upper press roll 3. The output shaft of the motor 5 is connected with a driving gear disc, one end of a driving chain 8 is connected with the driving gear disc, and the other end of the driving chain is connected with a lower driving gear disc 16. The upper pinion plate 15 is linked to the drive chain 8, and as can be seen from fig. 1, the drive chain 8 is located on the right side of the upper pinion plate 15. The drive gear plate and the lower drive gear plate 16 rotate in the same direction, and the upper drive gear plate 15 and the lower drive gear plate 16 rotate in the opposite direction.

The lower driven gear plate 7 is connected with the central shaft of the first lower press roll 4, the central shaft of the second lower press roll 10 is connected with a first duplicate gear, the central shaft of the third lower press roll 12 is connected with a second duplicate gear, and the central shaft of the fourth lower press roll 14 is connected with a gear. The first driven chain 17 is linked between the lower driven gear disc 7 and one of the gear parts of the first duplicate gear, and the second driven chain 18 is linked between the other gear part of the first duplicate gear and one of the gear parts of the second duplicate gear. The third driven chain 19 is linked between the other gear portion of the second duplicate gear and the gear on the central shaft of the fourth lower press roller 14.

The upper driven gear disc 6 is connected with a central shaft of the first upper pressing roller 3, a central shaft of the second upper pressing roller 9 is connected with a third duplicate gear, a central shaft of the third upper pressing roller 11 is connected with a fourth duplicate gear, and a central shaft of the fourth upper pressing roller 13 is connected with a gear. A fourth driven chain 20 is linked between the upper driven gear disc 6 and one of the gear parts of the third duplicate gear, a fifth driven chain 21 is linked between the other gear part of the third duplicate gear and one of the gear parts of the fourth duplicate gear, and a sixth driven chain 22 is linked between the other gear part of the fourth duplicate gear and the gear of the central shaft of the fourth upper press roller 13.

When the scallop cultivation cage extruding device works, referring to fig. 2, the motor 5 drives the first lower pressing roller 4 to rotate anticlockwise through the chain transmission mechanism, and meanwhile, the first upper pressing roller 3 rotates clockwise under the driving of the driving chain 8. The first lower pressing roller 4 sequentially drives the second lower pressing roller 10, the third lower pressing roller 12 and the fourth lower pressing roller 14 to rotate anticlockwise, and the first upper pressing roller 3 drives the second upper pressing roller 9, the third upper pressing roller 11 and the fourth upper pressing roller 13 to rotate clockwise. The scallop cultivation cages to be treated and stacked together are fed in from the position between the fourth upper press roll 13 and the fourth lower press roll 14, are extruded for four times and are finally output from the position between the first upper press roll 3 and the first lower press roll 4.

In the extrusion process, the fourth upper press roll 13, the third upper press roll 11, the first upper press roll 3 and the second upper press roll 9 can move upwards and reset under the action of the pressure spring.

After the laminated scallop cultivation cages are extruded, fouling organisms and silt attached to the laminated scallop cultivation cages can be crushed, and even a part of fouling organisms and silt fall off.

As shown in fig. 4 and 5, three striking devices 36 are mounted on the conveyor belt device 33, a drive motor 37 is mounted on the conveyor belt device 33, and a water tank 34 is mounted on the conveyor belt device 33. A water shield 35 is positioned above the conveyor belt assembly 33 and a water jet 38 is connected to the water shield 35.

The conveyor belt device 33 comprises a conveyor belt 3301, a front tension wheel 3302, a belt pressing wheel 3304, a rear tension wheel 3305, and a conveyor belt driving motor 3306, wherein the conveyor belt driving motor 3306 is connected with the rear tension wheel 3305, and the conveyor belt 3301 is connected between the front tension wheel 3302 and the rear tension wheel 3305. The conveyor 3301 is located at the bottom of the water trough 34.

As shown in fig. 6-9, the striking device 36 includes a bracket 3601, a striking belt 3602, a pressing plate device 3603, a hinge 3604, a rotating shaft 3605, a connecting rod 3606, and a driving wheel 3607. The rotating shaft 3605 is connected to the bracket 3601, and the rotating shaft 3605 can rotate by taking the bracket 3601 as a support.

The plate pressing device 3603 is welded on the rotating shaft 3605 through a connecting piece, one surface of the plate pressing device 3603 is provided with two connecting rod inserting holes 3608, and the other surface is also provided with two connecting rod inserting holes; the platen device 3603 includes a first pressing part 3609 and a second pressing part 3610. The pressing plate device 3603 wraps the rotating shaft 3605.

Two connecting rods 3606 pass through the two connecting rod insertion holes 3608 to be welded with the rotating shaft 3605, and the other two connecting rods are also inserted into the two connecting rod insertion holes on the other surface of the plate pressing device 3603 and welded on the rotating shaft 3605.

A plurality of striking strips 3602 are connected to a connecting rod 3606 by hinges 3604 (two or three striking strips work best). Because there are two oppositely disposed hinge members, there are two oppositely disposed striking belt sets.

The driving wheel 3607 is connected with the rotating shaft 3605, and the driving motor 37 is connected with the driving wheel 3607 through a transmission mechanism.

The holders 3601 are installed at both sides of the conveyor belt device 33.

The striking belt 3602 may be made of a rubber material. Hinge 3604 may specifically be a matching structure of a sleeve and a ring.

The driving motor 37 is used as a power source to drive the rotating shaft 3605 to rotate, and the rotating shaft 3605 drives the connecting rod 3606 and the pressing plate device 3603 to rotate, so that the striking belt 3602 swings and rotates in the counterclockwise direction in the drawing 6. The connecting rod 3606 may increase the radius of gyration of the striking belt 3602. The platen device 3603 has two functions, one is to prevent the two striking strips 3602 from interfering or winding together; secondly, the first pushing part 3609 and the second pushing part 3610 of the pressing plate device 3603 can apply certain pressure to the hinge 3604, so that the swinging of the striking belt 3602 is facilitated.

When the beating device 36 is used, the overlapped scallop cultivation cages are placed below the whipped beating belt 3602, so that the beating belt can continuously beat the scallop cultivation cages, fouling organisms and silt attached to the cultivation cages can be quickly beaten, the scallop cultivation cages are completely cleaned, and the cleaning efficiency is high.

For batch processing of the scallop cultivation cages, as shown in fig. 4, three striking devices 36 can be installed on the conveyor belt device 33, and the stacked scallop cultivation cages are sequentially placed on the conveyor belt device 33, so that each stacked scallop cultivation cage is sequentially struck by the three striking devices 36. Meanwhile, the water spraying pipe 38 firstly sprays water to wash the cultivation cage, and automatic cleaning operation is realized. The water is collected and drained by the water tank 34.

In order to achieve a better removing effect, before the beating device 36 is used for beating the scallop cultivation cage, the scallop cultivation cage extruding device is used for extruding the cultivation cages which are overlapped together, so that the beating device 36 can more thoroughly remove fouling organisms and silt.

The above description is only for the purpose of illustrating preferred embodiments of the present invention and is not to be construed as limiting the present invention, and it is apparent to those skilled in the art that various modifications and variations can be made in the present invention.

Claims (3)

1. A scallop cultivation cage removing device is characterized by comprising a striking device, wherein the striking device comprises a support, a striking belt, a rotating shaft and a connecting rod, the rotating shaft is connected to the support, the connecting rod is connected with the rotating shaft, and the striking belt is connected with the connecting rod through a hinge piece;

the pressing plate device is fixedly connected with the rotating shaft and provided with a connecting rod inserting hole, and the connecting rod penetrates through the connecting rod inserting hole to be connected with the rotating shaft; the pressing plate device is provided with a pushing part;

the number of the hinged parts is two, and the hinged parts are oppositely arranged; each hinged part is connected with a striking belt; the striking belt is made of rubber; the pressing plate device is provided with a first pushing part and a first pushing part;

the driving motor is connected with the rotating shaft through a transmission mechanism; when the driving motor drives the rotating shaft to rotate, the rotating shaft drives the connecting rod and the pressing plate device to rotate, so that the beating belt swings and rotates in the anticlockwise direction.

2. The removing device according to claim 1, further comprising a squeezing device, wherein the squeezing device comprises a frame, a motor, a first upper press roller, a first lower press roller, a second upper press roller, a second lower press roller, an upper driving gear disc, a lower driving gear disc, an upper driven gear disc, a lower driven gear disc, a driving chain, a first driven chain and a fourth driven chain, and the motor is connected with the frame; the first upper pressing roller, the first lower pressing roller, the second upper pressing roller and the second lower pressing roller are respectively provided with a central shaft;

two ends of a central shaft of the first lower pressing roller are respectively connected with the frame through bearing seat assemblies, and two ends of a central shaft of the second lower pressing roller are respectively connected with the frame through bearing seat assemblies; the two ends of the central shaft of the first upper press roller are respectively connected with the frame through sliding bearing seat assemblies, and the two ends of the central shaft of the second upper press roller are respectively connected with the frame through sliding bearing seat assemblies; a pressure spring is connected between the sliding bearing seat component and the frame;

the lower driving gear disc is connected with a central shaft of the first lower pressing roller, the upper driving gear disc is connected with a central shaft of the first upper pressing roller, and an output shaft of the motor is connected with a driving gear disc; one end of the driving chain is linked with the driving gear disc, and the other end of the driving chain is linked with the lower driving gear disc; the upper driving gear disc is linked with the driving chain, and the steering directions of the upper driving gear disc and the lower driving gear disc are opposite;

the lower driven gear disc is connected with a central shaft of the first lower pressing roller, a central shaft of the second lower pressing roller is connected with a gear, and the first driven chain is connected between the lower driven gear disc and the gear on the central shaft of the second lower pressing roller;

the upper driven gear disc is connected with a central shaft of the first upper pressing roller, a central shaft of the second upper pressing roller is connected with a gear, and the fourth driven chain is connected between the upper driven gear disc and the gear on the central shaft of the second upper pressing roller;

the extrusion device is connected with a third upper pressing roller, a third lower pressing roller, a fourth upper pressing roller and a fourth lower pressing roller, the third upper pressing roller is connected with the second upper pressing roller through a chain, the fourth upper pressing roller is connected with the third upper pressing roller through a chain, the third lower pressing roller is connected with the second lower pressing roller through a chain, and the fourth lower pressing roller is connected with the third lower pressing roller through a chain.

3. A cleaning device according to claim 2, further comprising conveyor means, said striking means being mounted on said conveyor means.

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