CN112681273B

CN112681273B - Wind power generation type automatic salvage equipment for marine garbage

Info

Publication number: CN112681273B
Application number: CN202110247007.3A
Authority: CN
Inventors: 江海城
Original assignee: State Grid Shanghai Electric Power Co Ltd
Current assignee: State Grid Shanghai Electric Power Co Ltd
Priority date: 2021-01-14
Filing date: 2021-03-05
Publication date: 2022-09-02
Anticipated expiration: 2041-03-05
Also published as: CN112681273A

Abstract

The invention relates to the relevant field of electromechanical equipment, in particular to wind power generation offshore garbage automatic fishing equipment. The utility model provides an automatic salvage equipment of wind power generation's marine rubbish, includes the organism, be equipped with in the organism and collect the chamber, it is equipped with the collection device who is used for collecting rubbish to collect the intracavity in the chamber, it is equipped with extrusion chamber to collect chamber collection chamber one side, but be equipped with the compaction in the extrusion chamber collect the compaction device of the rubbish that the intracavity was collected in the chamber, the compaction device can with the rubbish compaction in the extrusion chamber to realize the storage of a large amount of rubbish. The device can utilize wind power resources with huge reserves on the sea surface to generate electricity, does not need to drag a salvage ship, and has high resource utilization rate, energy conservation and environmental protection; can collect and the compaction with the marine rubbish in the certain area, need not to salvage the ship and regularly clear up the rubbish of salvaging in the equipment, can continuously work at sea, work efficiency is high.

Description

Wind power generation type automatic salvage equipment for marine garbage

Technical Field

The invention relates to the relevant technical field of electromechanical equipment, in particular to wind power generation offshore rubbish automatic fishing equipment.

Background

The advanced electromechanical equipment not only can greatly improve the labor productivity, reduce the labor intensity, improve the production environment and finish the work which can not be finished by manpower, but also has direct and important influence on the development of the whole national economy, the improvement of science and technology and national defense strength as one of national industrial foundations.

The conventional offshore garbage salvaging equipment needs to be dragged by a salvaging ship to move and cannot move by self, so that a large amount of energy is consumed for salvaging garbage, the cost is high, in addition, the general salvaging equipment needs to regularly clean the garbage in a machine body and does not have a garbage storage function, and the conventional salvaging equipment which can store more garbage while saving electricity is lacked.

Disclosure of Invention

The invention provides wind power generation offshore rubbish automatic fishing equipment aiming at the problems in the prior art.

The technical scheme adopted by the invention for solving the technical problems is as follows: an automatic salvage device for offshore garbage generated by wind power comprises a machine body, wherein a collection cavity is arranged in the machine body, a collection device for collecting garbage is arranged in the collection cavity, an extrusion cavity is arranged on one side of the collection cavity, a compaction device capable of compacting the garbage collected in the collection cavity is arranged in the extrusion cavity, the compaction device can compact the garbage in the extrusion cavity, so that a large amount of garbage is stored, a speed measuring chamber is arranged in the machine body, a steering device for testing the ocean current speeds on the left side and the right side of the machine body and controlling the steering of the machine body is arranged on the speed measuring chamber, a power generation chamber is fixedly connected to the end wall of the machine body far away from the sea surface, a power generation device for wind power generation is arranged in the power generation chamber, and the power generation device can generate power by utilizing wind power resources on the sea surface, for providing movement to the body.

Preferably, the collecting device comprises two connecting rods fixedly connected to the machine body, a moving frame fixedly connected to the connecting rods, a collecting net fixedly connected to an end wall on one side of each connecting rod, a collecting cavity arranged in the machine body, and a first through cavity arranged between the collecting cavity and end walls on two sides of the machine body; the collecting net is fixedly connected with the end walls of the two sides of the machine body.

Preferably, the compacting device includes a third transmission cavity provided in the machine body, a first threaded shaft provided in the third transmission cavity and rotatably connected with the collection cavity, a first sliding plate slidably connected with the collection cavity, a first through hole penetrating through the first sliding plate and provided in the first sliding plate, a screen fixedly connected with the end wall of the first through hole, a first sheave fixedly connected with the first threaded shaft in the third transmission cavity, a first motor fixedly connected with the end wall of one side of the third transmission cavity, a first motor shaft provided with one end of the first motor in power connection, a first turntable fixedly connected with the first motor shaft, a rotor fixedly connected with the first turntable, a carriage slidably connected with the third transmission cavity, a rack fixedly connected with the carriage, a second turntable fixedly connected with the first turntable, a second turntable fixedly connected with the second turntable, a second turntable fixedly connected with the third transmission cavity, and a second motor, A rack fixedly connected to one side end wall of the rack frame, a third rotating shaft rotatably connected to one side end wall of the third transmission cavity, a straight gear fixedly connected to the third rotating shaft, a second rotating disc fixedly connected to the third rotating shaft, an extrusion cavity arranged in the machine body, a second through cavity arranged between the extrusion cavity and the collection cavity, a second shaft sleeve rotatably connected between the extrusion cavity and the third transmission cavity, a second threaded shaft arranged in the second shaft sleeve in threaded connection, a second sliding plate fixedly connected to the second threaded shaft in the extrusion cavity, and a second grooved wheel fixedly connected to the second shaft sleeve in the third transmission cavity; the first threaded shaft is fixedly connected with the screen in the collection cavity; the rack is meshed with the straight gear; the second sliding plate is connected with the extrusion cavity in a sliding mode.

Preferably, the rotor is slidably connected to a slide groove provided in the carriage.

Preferably, a rotating pin which can be contacted with the first sheave and the second sheave is fixedly connected to one side end wall of the second rotary disc.

Preferably, the steering device includes a speed measuring chamber fixedly connected to the connecting rod, a speed measuring chamber arranged in the speed measuring chamber, a speed sensor fixedly connected to an end wall on one side of the speed measuring chamber, a first rotating shaft rotatably connected between the speed measuring chamber and the outside of the speed measuring chamber, a first impeller fixedly connected to the first rotating shaft, a second through hole penetrating the moving frame and formed in the moving frame, a first shaft sleeve rotatably connected to the second through hole, a third through hole penetrating the first shaft sleeve and formed in the first shaft sleeve, a second impeller fixedly connected to an end wall of the third through hole, a second transmission chamber arranged in an end wall of the second through hole, a third bevel gear fixedly connected to the first shaft sleeve and formed in the second transmission chamber, a first transmission chamber arranged in the machine body, a second impeller fixedly connected to an end wall of the third through hole, a second drive shaft, and a third shaft, The first transmission cavity is connected with the second transmission cavity in a rotating manner, the second transmission cavity is internally and fixedly connected with a second bevel gear, the second transmission cavity is internally and fixedly connected with a first bevel gear, two fourth transmission shafts are arranged on the end wall of one side of the first transmission cavity in a rotating manner, the fourth transmission shaft is fixedly connected with a fourth bevel gear, the fourth transmission shaft is internally and fixedly connected with a fifth transmission shaft in a spline connection manner, a first spline cavity is arranged in the fifth transmission shaft, a first spring is fixedly connected between the fourth transmission shaft and the bottom wall of the first spline cavity, a first V belt pulley is fixedly connected on the fifth transmission shaft, a second motor is fixedly connected in the end wall of one side of the first transmission cavity, and a second motor shaft is arranged at one end of the second motor in a power connection manner, A second spline cavity arranged in the end wall of one side of the second motor shaft, an electromagnetic switch fixedly connected in the second spline cavity, a sixth rotating shaft splined in the second spline cavity, a third V belt wheel fixedly connected to the sixth rotating shaft, a magnet fixedly connected to the sixth rotating shaft in the second spline cavity, and a second spring fixedly connected between the second motor shaft and the third V belt wheel, a seventh rotating shaft which is rotatably connected with the end wall at one side of the first transmission cavity, an eighth rotating shaft which is connected with a spline in the end wall at one side of the seventh rotating shaft, a second V belt wheel which is fixedly connected with the eighth rotating shaft, a third spring which is fixedly connected between the second V belt wheel and the seventh rotating shaft, and a V belt which is rotatably connected with the third spring, the third V belt wheel and the first V belt wheel; the inner wall of the first spline cavity is in spline connection with the fourth rotating shaft; the fourth bevel gear is meshed with the first bevel gear; the second bevel gear is meshed with the second transmission cavity.

Preferably, the power generation device comprises the power generation chamber, two fourth through holes penetrating through the power generation chamber and arranged in the power generation chamber, a fixing frame fixedly connected in the fourth through holes, a power generator fixedly connected in the end wall on one side of the fixing frame, a ninth rotating shaft arranged at one end of the power generator in a power connection mode, and a fan fixedly connected on the ninth rotating shaft.

Preferably, a searchlight is fixedly connected to the end wall of one side of the body in the sailing direction; the searchlight can enable other ships to find the device in time so as to avoid collision with the device.

The wind power generation automatic salvage equipment for the marine garbage has the advantages that wind power resources with huge reserves on the sea surface can be used for generating power, towing of salvage ships is not needed, the resource utilization rate is high, and the energy is saved and the environment is protected; the offshore garbage can be collected and compacted in a certain area, the garbage in fishing equipment is not required to be cleaned regularly by a fishing ship, the offshore garbage can continuously work, and the working efficiency is high; the garbage cleaning device is provided with the steering mechanism, so that the remote control operation of workers can be met, and the device can be controlled to reversely advance along the ocean current direction, so that the garbage cleaning efficiency of the device is higher.

Drawings

FIG. 1 is a schematic structural diagram of an offshore rubbish automatic salvage device with wind power generation;

FIG. 2 is a schematic view of the structure in the direction "A-A" of FIG. 1;

FIG. 3 is an enlarged view of the structure at "B" in FIG. 1;

FIG. 4 is a schematic view of the structure in the direction "C-C" of FIG. 1;

FIG. 5 is a schematic view of the structure in the direction "D-D" of FIG. 2;

FIG. 6 is a schematic view of the structure in the direction "E-E" of FIG. 4;

FIG. 7 is a schematic axial view of the automatic offshore garbage salvage device with wind power generation.

Detailed Description

The technical scheme of the invention is further explained by the specific implementation mode in combination with the attached drawings.

As shown in fig. 1-7, an automatic salvage device for offshore garbage by wind power generation comprises a machine body 10, a collection cavity 65 is arranged in the machine body 10, a collection device 991 for collecting garbage is arranged in the collection cavity 65, an extrusion cavity 11 is arranged on one side of the collection cavity 65, a compaction device 992 capable of compacting garbage collected in the collection cavity 65 is arranged in the extrusion cavity 11, the compaction device 992 can compact the garbage in the extrusion cavity 11 so as to realize storage of a large amount of garbage, a speed measuring chamber 21 is arranged in the machine body 10, a steering device 993 for testing the ocean current velocity on the left side and the right side of the machine body 10 and controlling the steering of the machine body 10 is arranged on the speed measuring chamber 21, a power generation chamber 34 is fixedly connected to the end wall of one side of the machine body 10 away from the ocean surface, the power generation room 34 of the power generation room is internally provided with a power generation device 994 for wind power generation, and the power generation device 994 can utilize wind power resources on the sea surface to generate power and is used for supplying the machine body to move.

The collecting device 991 comprises two connecting rods 20 fixedly connected to the machine body 10, a moving frame 26 fixedly connected to the connecting rods 20, a collecting net 75 fixedly connected to an end wall on one side of each connecting rod 20, a collecting cavity 65 arranged in the machine body 10, and a first through cavity 57 arranged between the collecting cavity 65 and end walls on two sides of the machine body 10; the collecting nets 75 are fixedly connected with the end walls of both sides of the machine body 10.

The compacting device 992 includes a third transmission cavity 58 arranged in the machine body 10, a first threaded shaft 15 rotatably connected between the third transmission cavity 58 and the collection cavity 65, a first sliding plate 13 slidably connected in the collection cavity 65, a first through hole 56 penetrating through the first sliding plate 13 and arranged in the first sliding plate 13, a screen 14 fixedly connected to an end wall of the first through hole 56, a first sheave 67 fixedly connected to the first threaded shaft 15 in the third transmission cavity 58, a first motor 60 fixedly connected to an end wall of one side of the third transmission cavity 58, a first motor shaft 59 dynamically connected to one end of the first motor 60, a first rotating disc 72 fixedly connected to the first motor shaft 59, a rotor 74 fixedly connected to the first rotating disc 72, a carriage 73 slidably connected in the third transmission cavity 58, a second motor shaft 14, A rack 64 fixedly connected with the carriage 73, a rack 63 fixedly connected with one side end wall of the rack 64, a third rotating shaft 61 rotatably connected with one side end wall of the third transmission cavity 58, a straight gear 62 fixedly connected with the third rotating shaft 61, a second rotating disc 68 fixedly connected with the third rotating shaft 61, and an extrusion cavity 11 arranged in the machine body 10, a second through cavity 12 arranged between the extrusion cavity 11 and the collection cavity 65, a second shaft sleeve 69 rotatably connected between the extrusion cavity 11 and the third transmission cavity 58, a second threaded shaft 71 connected with the second shaft sleeve 69 through an internal thread, a second sliding plate 66 fixedly connected with the second threaded shaft 71 in the extrusion cavity 11, and a second grooved pulley 70 fixedly connected with the second shaft sleeve 69 in the third transmission cavity 58; the first threaded shaft 15 is fixedly connected to the screen 14 within the collection chamber 65; the rack 63 is meshed with the straight gear 62; the second sliding plate 66 is slidably connected to the extrusion chamber 11.

The rotor 74 is slidably connected to a slide groove provided in the carriage 73.

A rotating pin which can be contacted with the first grooved pulley 67 and the second grooved pulley 70 is fixedly connected to one side end wall of the second rotating disc 68.

Steering device 993 includes on the connecting rod 20 fixed connection be equipped with the speed cell 21 the speed cell 23 that is equipped with in the speed cell 21, the speed sensor 22 that fixed connection was equipped with on the wall of the chamber 23 one side end of testing speed, the speed cell 23 with rotate the first pivot 24 that is equipped with of connection between the speed cell 21 outside, fixed connection be equipped with on the first pivot 24 first impeller 25, be equipped with in the removal frame 26 run through the second through-hole 29 of removal frame 26, the first axle sleeve 30 that is equipped with of second through-hole 29 internal rotation connection, be equipped with in the first axle sleeve 30 run through the third through-hole 32 of first axle sleeve 30, fixed connection be equipped with on the end wall of third through-hole 32 second impeller 33 on the end wall, be equipped with in the end wall of second through-hole 29 the first axle sleeve 30 is in the second transmission cavity 28 internal fixed connection be equipped with third bevel gear 31, first axle sleeve 30, A first transmission cavity 16 arranged in the machine body 10, a second rotating shaft 19 arranged between the first transmission cavity 16 and the second transmission cavity 28 in a rotating connection manner, a second bevel gear 27 arranged in the second transmission cavity 28 in a fixedly connecting manner, a first bevel gear 18 arranged in the first transmission cavity 16 in a fixedly connecting manner, two fourth rotating shafts 40 arranged in one side end wall of the first transmission cavity 16 in a rotating connection manner, a fourth bevel gear 17 arranged in the fourth rotating shaft 40 in a fixedly connecting manner, a fifth rotating shaft 76 arranged in a spline connection manner on the fourth rotating shaft 40, a first spline cavity 41 arranged in the fifth rotating shaft 76, a first spring 42 arranged in a fixedly connecting manner between the fourth rotating shaft 40 and the bottom wall of the first spline cavity 41, a first V-shaped belt pulley 43 arranged in a fixedly connecting manner on the fifth rotating shaft 76, a first bevel gear 18 arranged in a rotating connection manner, a second bevel gear 27 arranged in a rotating connection manner, and a second bevel gear 17 arranged in a fixedly connecting manner on the second rotating shaft 19 in the first transmission cavity 28, a rotating connection manner, The second motor 50 fixedly connected in the end wall of one side of the first transmission cavity 16, the second motor shaft 77 dynamically connected and provided in one end of the second motor 50, the second spline cavity 52 arranged in the end wall of one side of the second motor shaft 77, the electromagnetic switch 51 fixedly connected and provided in the second spline cavity 52, the sixth rotating shaft 54 connected and provided in the spline cavity 52, the third V belt pulley 45 fixedly connected and provided in the sixth rotating shaft 54, the magnet 53 fixedly connected and provided in the second spline cavity 52 in the sixth rotating shaft 54, the second spring 55 fixedly connected and provided between the second motor shaft 77 and the third V belt pulley 45, the seventh rotating shaft 48 rotatably connected and provided in the end wall of one side of the first transmission cavity 16, the eighth rotating shaft 49 fixedly connected and provided in the end wall of one side of the seventh rotating shaft 48, the second V belt pulley 46 fixedly connected and provided in the eighth rotating shaft 49, A third spring 47 fixedly connected between the second V-belt wheel 46 and the seventh rotating shaft 48, and a V-belt 44 arranged on the third spring 47, the third V-belt wheel 45 and the first V-belt wheel 43 in a transmission connection manner; the inner wall of the first spline cavity 41 is in spline connection with the fourth rotating shaft 40; the fourth bevel gear 17 is meshed with the first bevel gear 18; the second bevel gear 27 meshes with the second transmission chamber 28.

The power generation device 994 comprises the power generation chamber 34, two of the power generation chamber 34 run through the fourth through hole 35 of the power generation chamber 34, the fixing frame 36 fixedly connected in the fourth through hole 35 and provided with the power generator 39 fixedly connected in the end wall on one side of the fixing frame 36, the ninth rotating shaft 38 connected with one end of the power generator 39 in a power connection mode and the fan 37 fixedly connected in the ninth rotating shaft 38 and provided with the power generator.

A searchlight 78 is fixedly connected to the end wall of one side of the machine body 10 in the sailing direction; the searchlight 78 allows other boats to discover the device in a timely manner to avoid a collision with the device.

The use steps of the wind power generation offshore rubbish automatic fishing device are described in detail in the following with reference to fig. 1 to 7:

at the beginning, the second motor 50 rotates, the second motor 50 drives the second motor shaft 77 to rotate, the second motor shaft 77 drives the sixth rotating shaft 54 to rotate, the sixth rotating shaft 54 drives the third V-belt pulley 45 to rotate, the third V-belt pulley 45 drives the V-belt 44 to transmit, the V-belt 44 drives the first V-belt pulley 43 to rotate, the first V-belt pulley 43 drives the fifth rotating shaft 76 to rotate, the fifth rotating shaft 76 drives the fourth rotating shaft 40 to rotate, the fourth rotating shaft 40 drives the fourth bevel gear 17 to rotate, the fourth bevel gear 17 drives the first bevel gear 18 to rotate, the first bevel gear 18 drives the second rotating shaft 19 to rotate, the second rotating shaft 19 drives the second bevel gear 27 to rotate, the second bevel gear 27 drives the third bevel gear 31 to rotate, and the third bevel gear 31 drives the first shaft sleeve 30 to rotate, the first shaft sleeve 30 drives the second impeller 33 to rotate, the second impeller 33 drives the first shaft sleeve 30 to move downwards, the first shaft sleeve 30 drives the moving frame 26 to move downwards, the moving frame 26 drives the connecting rod 20 to move downwards, the connecting rod 20 drives the machine body 10 to move downwards, the connecting rod 20 drives the collecting net 75 to move downwards, the rubbish on the sea surface of the collecting net 75 is pushed to the machine body 10, and the rubbish enters the collecting cavity 65 through the first through cavity 57.

The first motor 60 is started, the first motor 60 drives the first motor shaft 59 to rotate, the first motor shaft 59 drives the first turntable 72 to rotate, the first turntable 72 drives the rotor 74 to rotate, the rotor 74 drives the carriage 73 to slide downwards, the carriage 73 drives the rack 64 to slide downwards, the rack 64 drives the rack 63 to slide downwards, the rack 63 drives the spur gear 62 to rotate, the spur gear 62 drives the third rotating shaft 61 to rotate, the third rotating shaft 61 drives the second turntable 68 to rotate, the rotating pin on the second turntable 68 contacts with the first grooved wheel 67 and drives the first grooved wheel 67 to rotate, the first grooved wheel 67 drives the first threaded shaft 15 to rotate, the first threaded shaft 15 drives the screen 14 to slide forwards, the screen 14 lifts the garbage in the collecting cavity 65 upwards, the garbage enters the extrusion chamber 11 through the second through-cavity 12, the rotating pin on the second rotary disk 68 is out of contact with the first sheave 67 and is in contact with the second sheave 70, the second rotary disk 68 drives the second sheave 70 to rotate, the second sheave 70 drives the second sleeve 69 to rotate, the second sleeve 69 drives the second threaded shaft 71 to move backward, the second threaded shaft 71 drives the second sliding plate 66 to slide backward, the second sliding plate 66 extrudes the garbage in the extrusion chamber 11, when the second sliding plate 66 moves to the rearmost end, the rotor 74 rotates to the lowermost end, the rotor 74 drives the carriage 73 to start moving upward, the carriage 73 drives the second rotary disk 68 to rotate reversely, the second rotary disk 68 drives the second sheave 70 to rotate reversely, and the second sheave 70 drives the second sliding plate 66 to move forward to the initial position, the rotating pin on the second turntable 68 is out of contact with the second sheave 70 and is in contact with the first sheave 67, the second turntable 68 drives the first sheave 67 to rotate reversely, and the first sheave 67 drives the screen 14 to move backward to the initial position.

When the connecting rod 20 moves downwards, the connecting rod 20 drives the speed measuring chamber 21 to move downwards, the speed measuring chamber 21 drives the first rotating shaft 24 to move downwards, the first rotating shaft 24 drives the first impeller 25 to move downwards, when the sea current passes through the first impeller 25, the first impeller 25 drives the first rotating shaft 24 to rotate, the speed sensor 22 measures the rotating speed of the first rotating shaft 24, when the rotating speed of the first rotating shaft 24 on the left side is higher, the sixth rotating shaft 54 is electrified with forward current and repels the magnet 53, the magnet 53 moves forwards and drives the sixth rotating shaft 54 to move forwards, the sixth rotating shaft 54 drives the third V belt pulley 45 to move forwards, the first V belt pulley 43 and the second V belt pulley 46 on the right side move towards the sides far away from each other, and the transmission ratio of the V belt 44 is increased, the first V pulley 43 on the left rotates at a lower speed than the first V pulley 43 on the right, so that the machine body 10 rotates to the left, and when the first rotating shaft 24 on the right rotates at a higher speed, the sixth rotating shaft 54 passes a reverse current and attracts the magnet 53, so that the first V pulley 43 on the left and the third V pulley 45 move to the side away from each other, and the first V pulley 43 on the left rotates at a higher speed than the first V pulley 43 on the right, so that the machine body 10 deflects to the right.

When the machine body 10 moves, the machine body 10 drives the power generation chamber 34 to move downwards, when wind passes through the fourth through hole 35, the fan 37 can be driven to rotate, the fan 37 drives the ninth rotating shaft 38 to rotate, the ninth rotating shaft 38 drives the main shaft in the power generator 39 to rotate, power is generated in the power generator 39 and is used for supplying power to the second motor 50, and finally the offshore garbage automatic salvage equipment adopting wind power generation is achieved.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention and do not limit the spirit and scope of the present invention. Various modifications and improvements of the technical solutions of the present invention may be made by those skilled in the art without departing from the design concept of the present invention, and the technical contents of the present invention are all described in the claims.

Claims

1. The utility model provides an automatic salvage equipment of wind power generation's marine rubbish, includes organism (10), its characterized in that: the garbage collecting machine is characterized in that a collecting cavity (65) is arranged in the machine body (10), a collecting device (991) used for collecting garbage is arranged in the collecting cavity (65), an extrusion cavity (11) is arranged on one side of the collecting cavity (65), a compacting device (992) capable of compacting the garbage collected in the collecting cavity (65) is arranged in the extrusion cavity (11), the compacting device (992) can compact the garbage in the extrusion cavity (11), so that a large amount of garbage is stored, a speed measuring chamber (21) is arranged in the machine body (10), a steering device (993) used for testing the ocean current speed of the left side and the right side of the machine body (10) and controlling the steering of the machine body (10) is arranged on the speed measuring chamber (21), a power generating chamber (34) is fixedly connected to the end wall of the sea surface of the machine body (10), and a power generating device (994) used for wind power generation is arranged in the power generating chamber (34), the power generation device (994) can generate power by utilizing wind power resources on the sea surface and is used for supplying the machine body to move; the collecting device (991) comprises two connecting rods (20) fixedly connected to the machine body (10), a moving frame (26) fixedly connected to the connecting rods (20), a collecting net (75) fixedly connected to one side end wall of each connecting rod (20), a collecting cavity (65) arranged in the machine body (10) and a first through cavity (57) arranged between the collecting cavity (65) and the two side end walls of the machine body (10); the collecting net (75) is fixedly connected with the end walls of the two sides of the machine body (10); the compacting device (992) comprises a third transmission cavity (58) arranged in the machine body (10), a first threaded shaft (15) rotatably connected between the third transmission cavity (58) and the collection cavity (65), a first sliding plate (13) arranged in the collection cavity (65) in a sliding connection manner, a first through hole (56) penetrating through the first sliding plate (13) and arranged in the first sliding plate (13), a screen (14) fixedly connected to the end wall of the first through hole (56) and arranged in the end wall, a first grooved pulley (67) fixedly connected in the third transmission cavity (58) and arranged on the first threaded shaft (15), a first motor (60) fixedly connected to the end wall of one side of the third transmission cavity (58), a first motor shaft (59) dynamically connected to one end of the first motor (60), a first rotary disc (72) fixedly connected to the first motor shaft (59) and arranged in the end wall, Fixed connection's rotor (74) that is equipped with on first carousel (72), sliding connection's carriage (73) that is equipped with in third transmission chamber (58), fixed connection's rack (64) that is equipped with on carriage (73), rack (63) that is equipped with on rack (64) one side end wall of fixed connection, rotate the third pivot (61) that is equipped with of connection on third transmission chamber (58) one side end wall, fixed connection's straight-teeth gear (62) that is equipped with on third pivot (61), fixed connection's second carousel (68) that is equipped with on third pivot (61), extrusion chamber (11) that are equipped with in organism (10), extrusion chamber (11) with collect second logical chamber (12) that is equipped with between chamber (65), extrusion chamber (11) with rotate second shaft sleeve (69) that is equipped with of connection between third transmission chamber (58), A second threaded shaft (71) is arranged in the second shaft sleeve (69) in a threaded connection manner, a second sliding plate (66) is fixedly connected with the second threaded shaft (71) in the extrusion cavity (11), and a second grooved pulley (70) is fixedly connected with the second shaft sleeve (69) in the third transmission cavity (58); the first threaded shaft (15) is fixedly connected with the screen (14) in the collection cavity (65); the rack (63) is meshed with the straight gear (62); the second sliding plate (66) is connected with the extrusion cavity (11) in a sliding mode.

2. The wind power generation offshore rubbish automatic fishing equipment according to claim 1, characterized in that: the rotor (74) is connected with a sliding groove arranged in the sliding frame (73) in a sliding way.

3. The wind power generation offshore rubbish automatic fishing equipment according to claim 2, characterized in that: and a rotating pin which can be in contact with the first grooved wheel (67) and the second grooved wheel (70) is fixedly connected to one side end wall of the second rotating disc (68).

4. The wind power generation offshore rubbish automatic fishing equipment according to claim 3, characterized in that: turn to device (993) and include fixed connection's room (21) that tests the speed that is equipped with on connecting rod (20) the chamber (23) that tests the speed that is equipped with in room (21) the speed test the speed sensor (22) that are equipped with of fixed connection on the wall of chamber (23) one side end of testing the speed chamber (23) with rotate first pivot (24) that are equipped with of connecting between the room (21) outside of testing the speed the first impeller (25) that are equipped with of fixed connection on first pivot (24) the running through that is equipped with in removal frame (26) the second through-hole (29) of removal frame (26), the first axle sleeve (30) that are equipped with of second through-hole (29) internal rotation connection the running through that is equipped with in first axle sleeve (30) the third through-hole (32) the second impeller (33) that is equipped with of fixed connection on the wall of third through-hole (32) end, A second transmission cavity (28) arranged in the end wall of the second through hole (29), a third bevel gear (31) fixedly connected in the second transmission cavity (28) by the first shaft sleeve (30), a first transmission cavity (16) arranged in the machine body (10), a second rotating shaft (19) rotatably connected between the first transmission cavity (16) and the second transmission cavity (28), a second bevel gear (27) fixedly connected in the second transmission cavity (28) by the second rotating shaft (19), a first bevel gear (18) fixedly connected in the first transmission cavity (16) by the second rotating shaft (19), two fourth rotating shafts (40) rotatably connected on the end wall of one side of the first transmission cavity (16), and a fourth bevel gear (17) fixedly connected in the fourth rotating shaft (40), Spline connection's fifth pivot (76) on fourth pivot (40) be equipped with first spline chamber (41) that is equipped with in fifth pivot (76), fourth pivot (40) with fixed connection's between first spline chamber (41) the first spring (42) that is equipped with in the diapire, fixed connection's first V band pulley (43) that is equipped with, first transmission chamber (16) one side end wall internal fixation is equipped with second motor (50), second motor shaft (77) that is equipped with of second motor (50) one end power connection, second spline chamber (52) that is equipped with in second motor shaft (77) one side end wall, fixed connection's electromagnetic switch (51) that is equipped with in second spline chamber (52), spline connection's sixth pivot (54) that is equipped with in second spline chamber (52), fixed connection's third V band pulley (45) that is equipped with on sixth pivot (54), The sixth rotating shaft (54) is fixedly connected with a magnet (53) arranged in the second spline cavity (52), a second spring (55) fixedly connected between the second motor shaft (77) and the third V belt wheel (45), a seventh rotating shaft (48) rotatably connected with one side end wall of the first transmission cavity (16), an eighth rotating shaft (49) connected with one side end wall of the seventh rotating shaft (48) in a spline manner, a second V belt wheel (46) fixedly connected with the eighth rotating shaft (49), a third spring (47) fixedly connected between the second V belt wheel (46) and the seventh rotating shaft (48), a third spring (47), a third V belt wheel (45) and a V belt (44) in transmission connection with the first V belt wheel (43); the inner wall of the first spline cavity (41) is in spline connection with the fourth rotating shaft (40); the fourth bevel gear (17) is meshed with the first bevel gear (18); the second bevel gear (27) meshes with the second transmission chamber (28).

5. The wind power generation offshore rubbish automatic fishing equipment according to claim 4, characterized in that: generating device (994) include power generation room (34) two that are equipped with in power generation room (34) run through fourth through-hole (35) of power generation room (34), mount (36) that fourth through-hole (35) internal fixation connected was equipped with, mount (36) one side end wall internal fixation connected be equipped with generator (39), generator (39) one end power connection be equipped with ninth pivot (38) and fixed connection go up fan (37) that are equipped with on ninth pivot (38).

6. The automatic salvage equipment for offshore garbage generated by wind power as claimed in claim 5, is characterized in that: a searchlight (78) is fixedly connected to the end wall of one side of the machine body (10) in the sailing direction; the searchlight (78) can enable other ships to find the device in time so as to avoid colliding with the device.