CN109277034B

CN109277034B - Method for manufacturing marine anticorrosive coating

Info

Publication number: CN109277034B
Application number: CN201811097955.8A
Authority: CN
Inventors: 李超
Original assignee: Individual
Current assignee: Individual
Priority date: 2018-09-20
Filing date: 2018-09-20
Publication date: 2021-10-08
Anticipated expiration: 2038-09-20
Also published as: CN109277034A

Abstract

The invention discloses a method for manufacturing an ocean anticorrosive coating, which comprises a bottom plate, wherein a supporting bottom frame is arranged on the bottom plate, a supporting top frame is fixedly arranged on the supporting bottom frame, mounting plates are fixedly arranged on the end surface of the right side of the supporting bottom frame in an up-and-down symmetrical manner, a storage barrel is arranged in each mounting plate, a storage space is arranged in each storage barrel, an embedding cavity is arranged in the end surface of the right side of the supporting bottom frame, a driving rotating shaft is rotatably matched and arranged between the top wall of each embedding cavity and the end surface of the top of the supporting bottom frame, a first gear is fixedly arranged at the tail end of the bottom of the driving rotating shaft, an outer gear ring which is mutually meshed with the first gear is fixedly arranged on the periphery of each storage barrel, a sliding cavity penetrates through the left side and the right side of the supporting top frame, and a cross beam frame extends rightwards in the sliding cavity.

Description

Method for manufacturing marine anticorrosive coating

Technical Field

The invention relates to the technical field of paint production and processing, in particular to a method for manufacturing a marine anticorrosive coating.

Background

The anticorrosive material is a material for inhibiting the chemical corrosion and the electrochemical corrosion of an anticorrosive object, and along with the development of the preparation technology of the anticorrosive material, the existing marine anticorrosive coating is applied more, mixing and stirring of preparation raw materials in the preparation process of the marine anticorrosive coating is a necessary process, the mixing efficiency of equipment for mixing and stirring the preparation raw materials of the marine anticorrosive coating is low, and in addition, the stirring blades in the mixing and stirring equipment are not convenient to disassemble, assemble and clean, so the improvement is needed.

Disclosure of Invention

The object of the present invention is to provide a method for producing marine anti-corrosive coatings, which overcomes the above-mentioned drawbacks of the prior art.

The method for manufacturing the marine anticorrosive coating comprises a bottom plate, wherein a supporting bottom frame is installed on the bottom plate, a supporting top frame is fixedly arranged on the supporting bottom frame, mounting plates are fixedly arranged on the right side end face of the supporting bottom frame in an up-and-down symmetrical mode, a storage barrel is arranged in each mounting plate, a storage space is arranged in each storage barrel, an embedding cavity is arranged in the right side end face of the supporting bottom frame, a driving rotating shaft is installed between the top wall of each embedding cavity and the top end face of the supporting bottom frame in a rotating matching mode, a first gear is fixedly arranged at the tail end of the bottom of each driving rotating shaft, an outer gear ring meshed with the first gear is fixedly arranged on the periphery of each storage barrel, a sliding cavity is arranged in the supporting top frame in a left-right penetrating mode, a cross beam frame is arranged in the sliding cavity in a rightward extending mode, a first transmission cavity is arranged in the cross beam frame in a left-right extending mode, a second transmission cavity is arranged in the cross beam frame on the upper side of the first transmission cavity in the rightward extending mode, the first transmission cavity and the second transmission cavity are internally provided with a first rotation shaft in a rotating fit manner, the first rotation shaft extends out of the end surface of the bottom of the cross beam frame, the bottom end of the first rotation shaft is fixedly provided with a first spline shaft, the end surface of the top of the driving rotation shaft is internally provided with a first spline cavity which is connected with the first spline shaft in a spline fit manner, the periphery of the first rotation shaft in the first transmission cavity is fixedly provided with a second gear, the left sides of the second gear are mutually meshed with each other and provided with a third gear, the third gear is rotatably arranged on the bottom wall of the first transmission cavity through a second rotation shaft, the end surface of the bottom of the cross beam frame, the end surface of the second rotation shaft extends out of the end surface of the bottom of the cross beam frame, the bottom end of the second rotation shaft is fixedly provided with a second spline shaft, a rotation sleeve is arranged in the bottom wall of the sliding cavity in a rotating fit manner, and a second spline cavity which is connected with the second spline shaft in a spline fit manner is arranged in the end surface of the rotation sleeve, drive motor is installed in the terminal power fit in rotation sleeve bottom, drive motor set firmly in crossbeam frame bottom terminal surface, in the second transmission intracavity first axis of rotation periphery has set firmly driving pulley, in the second transmission intracavity with the storage space is equipped with the (mixing) shaft relatively, the (mixing) shaft periphery has set firmly driven pulleys, driven pulleys with driving fit installs driving belt between the driving pulley, demountable installation has multiunit stirring vane in the (mixing) shaft.

Further technical scheme, the crossbeam frame top has set firmly the dress and has decided the piece, the dress decides the piece top and has set firmly flexible arm, flexible arm top power fit installs the pneumatic cylinder, the pneumatic cylinder set firmly in the slip chamber roof, the both sides wall symmetry is equipped with two sets of slide rails of leading around the slip chamber, both sides terminal surface symmetry be equipped with around the crossbeam frame with the slide rail sliding fit connection's that leads lead the slider.

In a further technical scheme, the stirring shaft penetrates through the upper end surface and the lower end surface of the cross beam, the top end surface extends downwards and is provided with an adjusting cavity, an adjusting rod is arranged in the adjusting cavity in a sliding fit manner, a first jacking spring is arranged between the end surface of the bottom of the adjusting rod and the bottom wall of the adjusting cavity in a jacking fit manner, a plurality of groups of openings are symmetrically arranged on the left side wall and the right side wall of the adjusting cavity, the stirring blades are in splicing fit connection with the openings, the bottom wall of the opening is communicated with a telescopic cavity, a locking block is arranged in the telescopic cavity in a sliding fit manner, the locking block is fixedly connected with the adjusting rod, a locking cavity which is in locking fit connection with the locking block is arranged in the end surface of the bottom of the stirring blade, the adjusting rod extends out the top end face of the stirring shaft and the top end is fixedly provided with a butt plate, the end face of the right side of the supporting top frame is fixedly provided with a transverse plate, and the end face of the bottom of the transverse plate is correspondingly provided with a pressing plate.

A material discharging cavity is formed in the bottom end face penetrating through the bottom of the material storage barrel in the material storage space, a switch cavity is formed in the left side wall of the material discharging cavity and penetrates through the left side end face of the material storage barrel, a material baffle and a non-slip plate are installed in the switch cavity in a sliding fit mode, a first inner cavity is arranged in the right side end face of the non-slip plate, a second inner cavity is arranged in the left side end face of the material baffle, a second jacking spring is fixedly arranged between the second inner cavity and the first inner cavity, a control sliding cavity is formed in the bottom wall of the switch cavity, a control sliding block is installed in the control sliding cavity in a sliding fit mode, the control sliding block is fixedly connected with the material baffle, a driving screw is installed in the control sliding block in a threaded fit mode, the right side extending tail end of the driving screw is connected with the right side wall of the control sliding cavity in a rotating fit mode, and the left side extending tail end of the driving screw is installed with a switch motor in a power fit mode, the switch motor is fixedly arranged in the inner wall of the left side of the control sliding cavity, a disc is fixedly arranged on the end face of the right side of the supporting underframe at the periphery of the storage bucket, an annular cavity for the storage bucket to extend into is arranged in the disc, an anti-slip rubber ring is arranged in the annular cavity, and an anti-slip sheet in friction fit with the anti-slip rubber ring is fixedly arranged on the end face of the left side of the anti-slip sheet.

The manufacturing method of the marine anticorrosive coating comprises the following steps:

in an initial state, each group of stirring blades extends into the material storage space, the cross beam frame is positioned at the bottom end of the sliding cavity, the first spline shaft extends into the first spline cavity, the second spline shaft extends into the second spline cavity, and the material baffle plate extends into the material discharge cavity and completely seals the material discharge cavity;

when the material mixing operation is needed, the raw materials for preparing the marine anticorrosive coating are put into the material storage space, the driving motor is started to drive the third gear to rotate, the third gear drives the stirring blade to rotate in the opposite direction to the material storage barrel, and at the moment, the raw materials for preparing the marine anticorrosive coating can be mixed and stirred;

when the material mixing operation is finished, stopping starting the driving motor, then starting the switch motor to drive the material baffle to slide leftwards, pushing the anti-slip plate to slide leftwards by the material baffle, and enabling the anti-slip piece to be in contact with the anti-slip rubber ring to enable the material storage barrel to reduce the inertia acting force and stop rotating, and meanwhile, enabling the material baffle to extend out of the material discharging cavity to discharge the raw materials for preparing the ocean anticorrosive coating after the mixing and stirring are finished;

when needs are to stirring vane cleaning work, start the pneumatic cylinder and pass through flexible arm pulling crossbeam frame and stably rise along leading the slideway, at this moment, first integral key shaft breaks away from first spline chamber, and second integral key shaft breaks away from second spline chamber, and presses the contact of pressing the board to the butt joint board and will press the board to pushing down, and at this moment, the regulation pole lapse, adjusts the pole and drives the locking piece gliding and break away from the locking chamber completely, and at this moment, stirring vane is in the unblock state, can take out stirring vane and wash work.

The invention has the beneficial effects that: when the material mixing operation is needed, the raw materials for preparing the marine anticorrosive coating are put into the material storage space, the driving motor is started to drive the third gear to rotate, the third gear drives the stirring blade to rotate in the opposite direction to the material storage barrel, and at the moment, the raw materials for preparing the marine anticorrosive coating can be mixed and stirred; its compounding is efficient, has solved the tradition and has only singly rotated the stirring through stirring vane and problem that efficiency is not high.

When the material mixing operation is finished, stopping starting the driving motor, then starting the switch motor to drive the material baffle to slide leftwards, pushing the anti-slip plate to slide leftwards by the material baffle, and enabling the anti-slip piece to be in contact with the anti-slip rubber ring to enable the material storage barrel to reduce the inertia acting force and stop rotating, and meanwhile, enabling the material baffle to extend out of the material discharging cavity to discharge the raw materials for preparing the ocean anticorrosive coating after the mixing and stirring are finished; thereby the work of arranging is conveniently carried out, need not artifical manual opening and closes the striker plate, and simultaneously, the inertia of reducible storage vat rotates, and stability in use is strong.

When needs are to stirring vane cleaning work, start the pneumatic cylinder and pass through flexible arm pulling crossbeam frame and stably rise along leading the slideway, at this moment, first integral key shaft breaks away from first spline chamber, second spline shaft breaks away from second spline chamber, and press the contact of pressing plate to butt joint board and will press the clamp plate to pushing down, at this moment, adjust the pole lapse, it drives the locking piece gliding and breaks away from the locking chamber completely to adjust the pole, at this moment, stirring vane is in the unblock state, can take out stirring vane and wash the work, thereby automatic control carries out the dismouting to stirring vane, need not artifical manual dismouting through instruments such as spanner, high durability and convenient use, and is worth using widely.

Drawings

FIG. 1 is a schematic view of the internal overall structure of a marine anticorrosive coating manufacturing method according to the present invention;

FIG. 2 is an enlarged schematic view of the structure at A in FIG. 1;

fig. 3 is an enlarged schematic view of B in fig. 1.

Detailed Description

The present invention is described in detail below with reference to fig. 1-3.

Referring to fig. 1-3, a method for manufacturing an ocean anticorrosive coating according to an embodiment of the present invention includes a bottom plate 10, a supporting bottom frame 11 is installed on the bottom plate 10, a supporting top frame 27 is fixedly installed on the supporting bottom frame 11, an installation plate 51 is vertically symmetrically and fixedly installed on a right side end surface of the supporting bottom frame 11, a storage barrel 46 is installed in the installation plate 51, a storage space 48 is installed in the storage barrel 46, an embedding cavity 12 is installed in the right side end surface of the supporting bottom frame 11, a driving rotating shaft 14 is installed between a top wall of the embedding cavity 12 and a top end surface of the supporting bottom frame 11 in a rotating and matching manner, a first gear 13 is fixedly installed at a bottom end of the driving rotating shaft 14, an outer toothed ring 47 mutually engaged with the first gear 13 is fixedly installed on an outer periphery of the storage barrel 46, a sliding cavity 25 is penetratingly installed in the supporting top frame 27 from left to right, a cross beam frame 39 is extended from the sliding cavity 25 to the right, extend about in the crossbeam frame 39 and be equipped with first transmission chamber 22, first transmission chamber 22 upside the crossbeam frame 39 is inside to extend to the right and is equipped with second transmission chamber 35, first transmission chamber 22 with second transmission chamber 35 internal rotation cooperation installs first rotation axis 33, first rotation axis 33 stretches out crossbeam frame 39 bottom end outside and the bottom end has set firmly first integral key shaft 15, be equipped with in the drive shaft 14 top end be used for with first integral key shaft 15 spline fit connection's first spline chamber 41, in the first transmission chamber 22 first rotation axis 33 periphery has set firmly second gear 42, second gear 42 left side intermeshing is equipped with third gear 21, third gear 21 passes through second rotation axis 20 and rotates to install first transmission chamber 22 diapire, second rotation axis 20 stretches out crossbeam frame 39 bottom outside and the bottom end has set firmly second spline shaft 18, rotation sleeve 17 is installed to wall internal rotation cooperation in sliding chamber 25, be equipped with in the rotation sleeve 17 terminal surface of top with second spline shaft 18 spline fit connection's second spline chamber 19, rotate sleeve 17 bottom end power fit and install driving motor 16, driving motor 16 set firmly in crossbeam frame 39 bottom terminal surface, in the second transmission chamber 35 first rotation axis 33 periphery has set firmly driving pulley 23, in the second transmission chamber 35 with storage space 48 is equipped with (mixing) shaft 43 relatively, the (mixing) shaft 43 periphery has set firmly driven pulley 38, driven pulley 38 with driving pulley 36 is installed to the transmission cooperation between the driving pulley 23, demountable installation has multiunit stirring vane 45 in the (mixing) shaft 43.

Beneficially or exemplarily, the top end of the beam frame 39 is fixedly provided with the fixing block 34, the top end of the fixing block 34 is fixedly provided with the telescopic arm 26, the top end of the telescopic arm 26 is provided with the pneumatic cylinder 28 in a dynamic fit manner, the pneumatic cylinder 28 is fixedly arranged in the top wall of the sliding cavity 25, two groups of guide rails 24 are symmetrically arranged on the front side wall and the rear side wall of the sliding cavity 25, and guide blocks connected with the guide rails 24 in a sliding fit manner are symmetrically arranged on the front side end face and the rear side end face of the beam frame 39, so that the lifting adjustment of the beam frame 39 is automatically and stably controlled, and the stirring blades 45 are controlled to extend into and out of the material storage space 48.

Beneficially or exemplarily, the stirring shaft 43 penetrates through the upper end surface and the lower end surface of the cross beam frame 39, the top end surface extends downward to form an adjusting cavity 61, the adjusting rod 44 is installed in the adjusting cavity 61 in a sliding fit manner, the first top pressure spring 65 is installed between the bottom end surface of the adjusting rod 44 and the bottom wall of the adjusting cavity 61 in a top pressure fit manner, a plurality of groups of openings 68 are symmetrically arranged on the left side wall and the right side wall of the adjusting cavity 61, the stirring blades 45 are connected with the openings 68 in a plugging fit manner, the bottom wall of the openings 68 is communicated with a telescopic cavity 64, the locking block 62 is installed in the telescopic cavity 64 in a sliding fit manner, the locking block 62 is fixedly connected with the adjusting rod 44, the locking cavity 67 connected with the locking block 62 in a locking fit manner is arranged in the bottom end surface of the stirring blades 45, the adjusting rod 44 extends out of the top end of the stirring shaft 43, and the top end is fixedly provided with the abutting plate 37, the transverse plate 31 is fixedly arranged on the end face of the right side of the supporting top frame 27, and the pressing plate 32 is arranged on the end face of the bottom of the transverse plate 31 and the abutting plate 37 oppositely, so that the stirring blades 45 are unlocked and locked automatically, and convenience in disassembling and assembling the stirring blades 45 is improved.

Beneficially or exemplarily, a discharging cavity 80 is formed in the bottom end face of the storage barrel 46 in the bottom wall of the storage space 48 in a penetrating manner, a switch cavity 79 is formed in the left side wall of the discharging cavity 80 in a penetrating manner, a baffle plate 78 and a non-slip plate 71 are installed in the switch cavity 79 in a sliding fit manner, a first inner cavity 81 is formed in the right side end face of the non-slip plate 71, a second inner cavity 76 is formed in the left side end face of the baffle plate 78, a second jacking spring 75 is fixedly arranged between the second inner cavity 76 and the first inner cavity 81, a control sliding cavity 73 is formed in the bottom wall of the switch cavity 79, a control sliding block 77 is installed in the control sliding cavity 73 in a sliding fit manner, the control sliding block 77 is fixedly connected with the baffle plate 78, a drive screw 74 is installed in the control sliding block 77 in a threaded fit manner, and the right extending end of the drive screw 74 is connected with the right side wall of the control sliding cavity 73 in a rotating fit manner, drive lead screw 74 left side extends terminal power fit and installs switch motor 72, switch motor 72 set firmly in the smooth chamber 73 left side inner wall of control, storage vat 46 periphery support 11 right side terminal surface and have set firmly disc 52, be equipped with in the disc 52 and be used for the annular chamber 53 that storage vat 46 stretched into, be equipped with limited slip rubber circle 54 in the annular chamber 53, limited slip board 71 left side terminal surface set firmly for with limited slip rubber circle 54 friction fit's limited slip piece 70 to automatic control striker plate 78 opens the chamber 80 of discharging and closes, and automatic control storage vat 46 stall simultaneously when the chamber 80 of discharging opens.

in an initial state, each group of stirring blades 45 extends into the material storage space 48, the beam frame 39 is located at the bottom end of the sliding cavity 25, the first spline shaft 15 extends into the first spline cavity 41, the second spline shaft 18 extends into the second spline cavity 19, and the baffle plate 78 extends into the discharge cavity 80 and completely seals the discharge cavity 80.

When the material mixing operation is needed, the raw materials for preparing the marine anticorrosive coating are put into the material storage space 48, the driving motor 16 is started to drive the third gear 21 to rotate, the third gear 21 drives the stirring blades 45 to rotate in the opposite direction to the material storage barrel 46, and at the moment, the raw materials for preparing the marine anticorrosive coating can be mixed and stirred;

when the material mixing operation is finished, the driving motor 16 is stopped to be started, then the switch motor 72 is started to drive the material baffle plate 78 to slide leftwards, the material baffle plate 78 pushes the anti-slip plate 71 to slide leftwards, the anti-slip sheet 70 is made to contact with the anti-slip rubber ring 54, so that the material storage barrel 46 reduces the inertia acting force to stop rotating, and meanwhile, the material baffle plate 78 extends out of the material discharge cavity 80 to discharge the raw materials for preparing the marine anticorrosive coatings after the mixing and stirring are finished;

when the stirring blades need to be cleaned, the pneumatic cylinder 28 is started to pull the cross beam frame 39 to stably rise along the guide sliding rail 24 through the telescopic arm 26, at the moment, the first spline shaft 15 is separated from the first spline cavity 41, the second spline shaft 18 is separated from the second spline cavity 19, the pressing plate 32 is contacted with the abutting plate 37 and presses the pressing plate 32 downwards, at the moment, the adjusting rod 44 slides downwards, the adjusting rod 44 drives the locking block 62 to slide downwards and completely separate from the locking cavity 67, at the moment, the stirring blades 45 are in an unlocking state, and the stirring blades 45 can be taken out to be cleaned.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims

1. A manufacturing method of a marine anticorrosive coating comprises a bottom plate, and is characterized in that: the bottom plate is provided with a supporting bottom frame, a supporting top frame is fixedly arranged on the supporting bottom frame, mounting plates are fixedly arranged on the right side end face of the supporting bottom frame in an up-and-down symmetrical mode, a storage barrel is arranged in each mounting plate, a storage space is arranged in each storage barrel, an embedding cavity is arranged in the right side end face of the supporting bottom frame, a driving rotating shaft is arranged between the top wall of the embedding cavity and the top end face of the supporting bottom frame in a rotating fit mode, a first gear is fixedly arranged at the bottom end of the driving rotating shaft, an outer toothed ring meshed with the first gear is fixedly arranged on the periphery of each storage barrel, a sliding cavity is arranged in the supporting top frame in a left-and-right penetrating mode, a cross beam frame is arranged in the sliding cavity in a right-extending mode, a first transmission cavity is arranged in the cross beam frame in a left-and-right extending mode, a second transmission cavity is arranged in the cross beam frame on the upper side of the first transmission cavity in a right-extending mode, and a first transmission shaft is arranged in a rotating fit mode in the first transmission cavity and the second transmission cavity in a rotating fit mode, the first rotating shaft extends out of the end face of the bottom of the cross beam frame, the tail end of the bottom of the first rotating shaft is fixedly provided with a first spline shaft, a first spline cavity which is connected with the first spline shaft in a spline fit manner is arranged in the end face of the top of the driving rotating shaft, a second gear is fixedly arranged on the periphery of the first rotating shaft in the first transmission cavity, a third gear is arranged on the left side of the second gear in a mutually meshed manner, the third gear is rotatably arranged on the bottom wall of the first transmission cavity through a second rotating shaft, the second rotating shaft extends out of the end face of the bottom of the cross beam frame, the tail end of the bottom of the cross beam frame is fixedly provided with a second spline shaft, a rotating sleeve is arranged in the bottom wall of the sliding cavity in a rotating fit manner, a second spline cavity which is connected with the second spline shaft in a spline fit manner is arranged in the end face of the top of the rotating sleeve, a driving motor is fixedly arranged on the end face of the bottom of the cross beam frame, a driving belt wheel is fixedly arranged on the periphery of the first rotating shaft in the second transmission cavity, a stirring shaft is arranged in the second transmission cavity opposite to the material storage space, a driven belt wheel is fixedly arranged on the periphery of the stirring shaft, a transmission belt is arranged between the driven belt wheel and the driving belt wheel in a transmission fit mode, and a plurality of groups of stirring blades are detachably arranged in the stirring shaft; an installation block is fixedly arranged at the top end of the beam frame, a telescopic arm is fixedly arranged at the top end of the installation block, a pneumatic cylinder is installed at the top end of the telescopic arm in a power fit mode, the pneumatic cylinder is fixedly arranged in the top wall of the sliding cavity, two groups of guide rails are symmetrically arranged on the front side wall and the rear side wall of the sliding cavity, and guide sliding blocks in sliding fit connection with the guide rails are symmetrically arranged on the front side end face and the rear side end face of the beam frame; the stirring shaft penetrates through the upper end surface and the lower end surface of the cross beam frame, the top end surface of the stirring shaft extends downwards to form an adjusting cavity, an adjusting rod is arranged in the adjusting cavity in a sliding fit manner, a first jacking spring is arranged between the end surface of the bottom of the adjusting rod and the bottom wall of the adjusting cavity in a jacking fit manner, a plurality of groups of openings are symmetrically arranged on the left side wall and the right side wall of the adjusting cavity, the stirring blades are in splicing fit connection with the openings, the bottom wall of the opening is communicated with a telescopic cavity, a locking block is arranged in the telescopic cavity in a sliding fit manner, the locking block is fixedly connected with the adjusting rod, a locking cavity which is in locking fit connection with the locking block is arranged in the end surface of the bottom of the stirring blade, the adjusting rod extends out of the end surface of the top of the stirring shaft, the tail end of the top of the adjusting rod is fixedly provided with a butt plate, the end surface of the right side of the supporting top frame is fixedly provided with a transverse plate, and the end surface of the bottom of the transverse plate is provided with a pressing plate opposite to the butt plate; the material storage device is characterized in that a material discharging cavity is formed in the bottom end face of the material storage barrel and penetrates through the inner wall of the material storage space, a switch cavity is formed in the left side wall of the material discharging cavity and penetrates through the left side end face of the material storage barrel, a material baffle plate and a non-slip plate are installed in the switch cavity in a sliding fit mode, a first inner cavity is formed in the right side end face of the non-slip plate, a second inner cavity is formed in the left side end face of the material baffle plate, a second jacking spring is fixedly arranged between the second inner cavity and the first inner cavity, a control slip cavity is formed in the bottom wall of the switch cavity, a control slider is installed in the control slip cavity in a sliding fit mode and is fixedly connected with the material baffle plate, a driving screw is installed in the control slider in a thread fit mode, the right extending end of the driving screw is connected with the right side wall of the control slip cavity in a rotating fit mode, and a switch motor is installed in the left extending end of the driving screw in a power fit mode, the switch motor is fixedly arranged in the inner wall of the left side of the control sliding cavity, a disc is fixedly arranged on the end face of the right side of the supporting underframe at the periphery of the storage bucket, an annular cavity for the storage bucket to extend into is arranged in the disc, an anti-slip rubber ring is arranged in the annular cavity, and an anti-slip sheet in friction fit with the anti-slip rubber ring is fixedly arranged on the end face of the left side of the anti-slip sheet; the manufacturing method of the marine anticorrosive coating comprises the following steps: in an initial state, each group of stirring blades extends into the material storage space, the cross beam frame is positioned at the bottom end of the sliding cavity, the first spline shaft extends into the first spline cavity, the second spline shaft extends into the second spline cavity, and the material baffle plate extends into the material discharge cavity and completely seals the material discharge cavity; when the material mixing operation is needed, the raw materials for preparing the marine anticorrosive coating are put into the material storage space, the driving motor is started to drive the third gear to rotate, the third gear drives the stirring blade to rotate in the opposite direction to the material storage barrel, and at the moment, the raw materials for preparing the marine anticorrosive coating can be mixed and stirred; when the material mixing operation is finished, stopping starting the driving motor, then starting the switch motor to drive the material baffle to slide leftwards, pushing the anti-slip plate to slide leftwards by the material baffle, and enabling the anti-slip piece to be in contact with the anti-slip rubber ring to enable the material storage barrel to reduce the inertia acting force and stop rotating, and meanwhile, enabling the material baffle to extend out of the material discharging cavity to discharge the raw materials for preparing the ocean anticorrosive coating after the mixing and stirring are finished; when needs are to stirring vane cleaning work, start the pneumatic cylinder and pass through flexible arm pulling crossbeam frame and stably rise along leading the slideway, at this moment, first integral key shaft breaks away from first spline chamber, and second integral key shaft breaks away from second spline chamber, and presses the contact of pressing the board to the butt joint board and will press the board to pushing down, and at this moment, the regulation pole lapse, adjusts the pole and drives the locking piece gliding and break away from the locking chamber completely, and at this moment, stirring vane is in the unblock state, can take out stirring vane and wash work.