CN111282674A

CN111282674A - Dyestuff reducing mechanism

Info

Publication number: CN111282674A
Application number: CN202010192290.XA
Authority: CN
Inventors: 不公告发明人
Original assignee: Hangzhou Najia Garment Co Ltd
Current assignee: GUANGCHANG LIHUA TECHNOLOGY Co.,Ltd.
Priority date: 2020-03-18
Filing date: 2020-03-18
Publication date: 2020-06-16
Anticipated expiration: 2040-03-18
Also published as: CN111282674B; JP2021146328A

Abstract

The invention discloses a dye crushing device which comprises a machine body, wherein a flow dividing cavity is arranged in the machine body, a feed inlet communicated with the outside is formed in the top wall of the flow dividing cavity, a fixed block fixedly connected with front and rear end walls is arranged in the flow dividing cavity, a third groove with an upward opening is formed in the upper end wall of the fixed block, an auxiliary transmission device is arranged in the third groove, a first movable cavity is formed in the lower side of the third groove of the fixed block, a first motor is fixedly installed on the left end wall of the first movable cavity, the first motor is in power connection with a first transmission shaft, a sixth helical gear is fixedly installed on the first transmission shaft, and the sixth helical gear is meshed with the first helical gear.

Description

Dyestuff reducing mechanism

Technical Field

The invention relates to the technical field of dyes, in particular to a dye crushing device.

Background

The dye has wide application range and is required to be used in a plurality of industrial production. For convenience of use and handling, many finished dyes are powdered. However, the dyes are easy to stack after a large number of purchases, the dyes are placed in corners, part of the dyes are agglomerated and inconvenient to perform subsequent processing, the conventional processing is performed by knocking and crushing through a crusher, and the possibility of different sizes and inconvenient subsequent dissolution are caused in the conventional processing.

Disclosure of Invention

Aiming at the technical defects, the invention provides a dye crushing device which can overcome the defects.

The dye crushing device comprises a machine body, wherein a flow dividing cavity is arranged in the machine body, a feed inlet communicated with the outside is formed in the top wall of the flow dividing cavity, a fixed block fixedly connected with front and rear end walls is arranged in the flow dividing cavity, a third groove with an upward opening is formed in the upper end wall of the fixed block, an auxiliary transmission device is arranged in the third groove, a first movable cavity is arranged on the lower side of the third groove of the fixed block, a first motor is fixedly arranged on the left end wall of the first movable cavity, the first motor is in power connection with a first transmission shaft, a sixth helical gear is fixedly arranged on the first transmission shaft, the sixth helical gear is meshed with a first helical gear, the first helical gear is fixedly arranged on a main transmission shaft, the main transmission shaft is in rotary connection with the upper and lower end walls of the first movable cavity, and rotary grooves are symmetrically formed in the left and right sides of, the rotary groove is characterized in that first limiting grooves are arranged in the left side wall and the right side wall of the rotary groove, the first limiting grooves are connected with second limiting grooves, movable rods are arranged in the second limiting grooves in a sliding fit mode, second springs connected with the movable rods are fixedly arranged on the bottom walls of the second limiting grooves, fifth rotating shafts are rotatably arranged on the movable rods, rollers are fixedly arranged on the fifth rotating shafts, material cylinders are arranged on the rollers, annular grooves are formed in the top walls of the shunting cavities, the upper ends of the rollers extend into the annular grooves, filter plates are fixedly arranged on the walls of the rollers, stirring cavities are formed in the lower ends of the fixed blocks, the lower ends of main transmission shafts extend into the stirring cavities to be rotatably connected with the stirring bottom walls, impellers are fixedly connected with the main transmission shafts in the stirring cavities, first grooves are formed in the right end walls of the stirring cavities, discharge ports are connected to the right sides of the first, a main transmission device is arranged in the first movable cavity.

Preferably, the auxiliary transmission device comprises a main transmission shaft, the upper end of the main transmission shaft extends into the third groove and is in rotating connection with the bottom wall of the third groove, the main transmission shaft is fixedly connected with a first friction disc and a third gear in the third groove, the left side and the right side of the third gear are symmetrically meshed with a second gear, the second gear is fixedly installed in a fourth rotating shaft, the fourth rotating shaft is rotatably installed on a movable plate in a sliding fit mode with the third groove, a through hole is formed in the movable plate, the main transmission shaft penetrates through the through hole, the bottom wall of the charging barrel is fixedly installed in the third groove with a second friction disc, a spline sleeve is connected to the fourth rotating shaft through a spline, the spline sleeve is rotatably installed on the bottom wall of the charging barrel, and a cutter is fixedly installed in the charging barrel at the upper end of the fourth rotating shaft.

Preferably, the main transmission device comprises a second motor fixedly mounted on the upper end wall of the first movable cavity, the second motor is in power connection with a second transmission shaft, a first belt pulley is fixedly mounted on the second transmission shaft, the first belt pulley is connected with a second belt pulley through a first conveyor belt, the second belt pulley is fixedly mounted on a second spline sleeve, a second movable cavity is arranged on the left side of the first movable cavity, the second spline sleeve is rotatably mounted on a wall body between the first movable cavity and the second movable cavity, a fourth transmission shaft is in spline connection in the second spline sleeve, a push rod is rotatably connected on the right side of the third transmission shaft, the push rod is in sliding fit with the right end wall of the first movable cavity and penetrates through the machine body, a round platform is fixedly mounted on the right side of the third transmission shaft, a second helical gear is in sliding fit with the round platform, and a T-shaped annular groove is arranged on the right end wall of the second helical gear, a fixed rod is rotationally matched in the T-shaped ring groove, and the right end of the fixed rod is fixedly arranged on the right end wall of the first movable cavity.

Preferably, first activity chamber downside is equipped with the chamber of drawing water, the chamber right side of drawing water is equipped with the water inlet, the chamber left side of drawing water be equipped with the delivery port that the stirring chamber is connected, it installs the third transmission shaft to rotate on the chamber bottom wall to draw water, fixed mounting has the second helical gear on the third transmission shaft, stretch into third transmission shaft upper end first activity chamber fixedly connected with third helical gear, the meshing of third helical gear upper end the second helical gear.

Preferably, the second activity chamber upper end is equipped with the third spout, be equipped with the ascending second recess of opening on the third spout diapire, the second recess with rotate on the wall body between the second activity chamber and install the second pivot, second pivot lower extreme stretches into second activity intracavity fixedly connected with fourth helical gear meshed's fifth helical gear, second pivot upper end in fixedly connected with seventh helical gear in the second recess, seventh helical gear meshing has the eighth helical gear, eighth helical gear fixed mounting is in the third pivot, the third pivot rotate install in end wall around the second recess, fixed mounting has first gear on the third back of changeing, first gear upper end in the third spout internal gearing has the rack, rack sliding fit the third spout.

Preferably, the right end wall of the fixed block is provided with a first chute, the left side wall of the first chute is provided with a hydraulic cavity, a first piston plate is arranged on the right side of the hydraulic cavity, a first mandril is fixedly arranged on the first piston plate, the left end of the first ejector rod extends into the first sliding groove and is in sliding fit with a wall body between the first sliding groove and the hydraulic cavity, the first top rod is connected with the left end wall of the first sliding chute in the first sliding chute through a first spring, a fourth chute with a leftward opening is arranged on the left side of the hydraulic cavity, a fourth piston plate is arranged on the left side of the hydraulic cavity, the fourth piston plate is fixedly connected with a second ejector rod which extends into the fourth sliding groove and is in sliding fit with a wall body between the fourth sliding groove and the hydraulic cavity, the second ejector rod is fixedly connected with a second partition plate in the fourth sliding groove, and the second partition plate is in sliding fit with the fourth sliding groove.

Preferably, a third limiting groove is formed in the left end wall of the diversion cavity and is symmetrical to the fourth sliding groove, a second movable block is in sliding fit with the third limiting groove, and the second movable block is connected with the third limiting groove through a third spring.

The beneficial effects are that: this device simple structure, convenient operation, through final drive shaft drives the feed cylinder rotation with the cutter rotates, guarantees that the dyestuff smashes efficiency, through the filter plate control dyestuff smashes the degree, through push rod control the reposition of redundant personnel chamber with the separation in stirring chamber is the discharge of the dyestuff of control stirring completion simultaneously.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural view of a dye pulverizing apparatus 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 view of the structure at B in FIG. 1;

fig. 4 is an enlarged schematic view of the structure at C in fig. 1.

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.

The invention will now be described in detail with reference to fig. 1-4, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The dye crushing device comprises a machine body 2, a shunting cavity 3 is arranged in the machine body 2, a feed inlet 1 communicated with the outside is arranged on the top wall of the shunting cavity 3, a fixed block 17 fixedly connected with front and rear end walls is arranged in the shunting cavity 3, a third groove 65 with an upward opening is arranged on the upper end wall of the fixed block 17, an auxiliary transmission device is arranged in the third groove 65, a first movable cavity 4 is arranged on the lower side of the third groove 65 of the fixed block 17, a first motor 18 is fixedly arranged on the left end wall of the first movable cavity 4, the first motor 18 is in power connection with a first transmission shaft 19, a sixth helical gear 9 is fixedly arranged on the first transmission shaft 19, the sixth helical gear 9 is meshed with the first helical gear 16, the first helical gear 16 is fixedly arranged on a main transmission shaft 22, the main transmission shaft 22 is in rotary connection with the upper and lower end walls of the first movable cavity 4, the fixed block 17 roof in third recess 65 left and right sides symmetry is equipped with the turn trough 69, be equipped with first spacing groove 68 in the both sides wall of turn trough 69 left and right sides, first spacing groove 68 is connected with second spacing groove 72, sliding fit installs the movable rod 70 in the second spacing groove 72, fixed mounting has on the second spacing groove 72 diapire with the second spring 71 that movable rod 70 is connected, rotating mounting has fifth pivot 67 on the movable rod 70, fixed mounting has gyro wheel 66 on the fifth pivot 67, be equipped with feed cylinder 13 on the gyro wheel 66, be equipped with annular 12 on the reposition of redundant personnel chamber 3 roof, cylinder 13 upper end stretches into annular 12, cylinder 13 wall fixed mounting has filter plate 14, fixed block 17 lower extreme is equipped with stirring chamber 20, final drive shaft 22 lower extreme stretches into stirring chamber 20 rotates to be connected the stirring 20 diapire, final drive shaft 22 in fixedly connected with impeller 21 in the stirring chamber 20, the stirring chamber 20 right-hand member wall is equipped with first recess 23, the escape orifice 11 is connected on first recess 23 right side, be equipped with first activity chamber 30 in the stirring chamber 20 right-hand member wall, be equipped with main gear in the first activity chamber 30.

Advantageously, said secondary transmission means comprise said main transmission shaft 22, the upper end of which protrudes into said third recess 65 and is rotatably connected to the bottom wall of said third recess 65, a first friction disc 78 and a third gear 76 are fixedly connected to the main drive shaft 22 within the third recess 65, the second gears 73 are symmetrically engaged with the left and right sides of the third gear 76, the second gears 73 are fixedly installed on the fourth rotating shaft 63, the fourth rotating shaft 63 is rotatably mounted on a movable plate 74, the movable plate 74 is slidably engaged with the third groove 65, the movable plate 74 is provided therein with a through hole 75, the main transmission shaft 22 passes through the through hole 75, a second friction disk 79 is fixedly mounted on the bottom wall of the charging barrel 13 in the third groove 65, spline connection has spline sleeve 80 on the fourth pivot 63, spline sleeve 80 rotate install in the feed cylinder 13 diapire, the fourth pivot 63 upper end stretches into fixed mounting has cutter 15 in the feed cylinder 13.

Advantageously, the main transmission device comprises a second motor 29 fixedly mounted on the upper end wall of the first movable cavity 30, the second motor 29 is in power connection with a second transmission shaft 28, a first belt pulley 27 is fixedly mounted on the second transmission shaft 28, the first belt pulley 27 is connected with a second belt pulley 31 through a first conveyor belt 26, the second belt pulley 31 is fixedly mounted on a second splined sleeve 42, a second movable cavity 64 is arranged on the left side of the first movable cavity 30, the second splined sleeve 42 is rotatably mounted on the wall body between the first movable cavity 30 and the second movable cavity 64, a fourth transmission shaft 43 is in splined connection with the second splined sleeve 42, a push rod 34 is rotatably connected on the right side of the third transmission shaft 43, the push rod 34 is in sliding fit with the right end wall of the first movable cavity 30 and penetrates through the machine body 2, a circular truncated cone 33 is fixedly mounted on the right side of the third transmission shaft 43, the circular truncated cone 33 is in sliding fit with a second bevel gear 32, a T-shaped ring groove 36 is formed in the right end wall of the second bevel gear 32, a fixed rod 35 is rotationally matched in the T-shaped ring groove 36, and the right end of the fixed rod 35 is fixedly installed on the right end wall of the first movable cavity 30.

Beneficially, a water pumping cavity 38 is arranged on the lower side of the first movable cavity 30, a water inlet is arranged on the right side of the water pumping cavity 38, a water outlet 41 connected with the stirring cavity 20 is arranged on the left side of the water pumping cavity 38, a third transmission shaft 40 is rotatably mounted on the bottom wall of the water pumping cavity 38, a second helical gear 39 is fixedly mounted on the third transmission shaft 40, a third helical gear 37 is fixedly connected with the first movable cavity 30 and is extended into the upper end of the third transmission shaft 40, and the upper end of the third helical gear 37 is engaged with the second helical gear 32.

Advantageously, the left end of the fourth transmission shaft 43 extends into the second transmission cavity 64 and is fixedly connected with a first friction block 44, the left end wall of the second movable cavity 64 is rotatably mounted with a first rotating shaft 52, the first rotating shaft 52 is fixedly mounted with a fourth pulley 53 and a fourth helical gear 47, the right end face of the fourth helical gear 47 is fixedly mounted with a second friction block 45, the left end wall of the second movable cavity 64 is rotatably mounted with a worm 50, the worm 50 is fixedly mounted with a third pulley 46, the third pulley 46 is connected with the fourth pulley 53 through a second transmission belt 51, the worm 50 is engaged with a worm wheel 49, the worm wheel 49 is fixedly mounted on a screw 48, the lower side of the second movable cavity 64 is provided with a second sliding groove 24, the lower end of the screw 48 extends into the second sliding groove 24 and is rotatably engaged with a wall body between the second sliding groove 24 and the second movable cavity 64, the screw 48 is in threaded connection with a partition 25 in sliding fit with the second sliding chute 24, and the second sliding chute 24 penetrates through the groove 23.

Beneficially, a third sliding groove 63 is provided at the upper end of the second movable cavity 64, a second groove 61 with an upward opening is provided at the bottom wall of the third sliding groove 63, a second rotating shaft 55 is rotatably installed on the wall body between the second groove 16 and the second movable cavity 64, the lower end of the second rotating shaft 55 extends into the second movable cavity 6 and is fixedly connected with a fifth helical gear 54 engaged with the fourth helical gear 47, a seventh helical gear 56 is fixedly connected at the upper end of the second rotating shaft 55 in the second groove 61, the seventh helical gear 56 is engaged with an eighth helical gear 58, the eighth helical gear 58 is fixedly installed on the third rotating shaft 53, the third rotating shaft 53 is rotatably installed on the front and rear end walls of the second groove 61, a first gear 59 is fixedly installed on the third rotating shaft 53, a rack 60 is engaged with the upper end of the first gear 59 in the third sliding groove 62, the rack 60 is slidably engaged with the third slide groove 62.

Advantageously, a first sliding groove 8 is formed in a right end wall of the fixed block 17, a hydraulic chamber 10 is formed in a left side wall of the first sliding groove 8, a first piston plate 5 is arranged on a right side of the hydraulic chamber 10, a first ram 6 is fixedly mounted on the first piston plate 5, a left end of the first ram 6 extends into the first sliding groove 8 and is in sliding fit with a wall body between the first sliding groove 8 and the hydraulic chamber 10, the first ram 6 is connected with a left end wall of the first sliding groove 8 in the first sliding groove 8 through a first spring 7, a fourth sliding groove 86 with a left opening is formed in a left side of the hydraulic chamber 10, a fourth piston plate 87 is arranged in the hydraulic chamber 10, the fourth piston plate 87 is fixedly connected with a second ram 85 which extends into the fourth sliding groove 86 and is in sliding fit with a wall body between the fourth sliding groove 87 and the hydraulic chamber 10, a second partition 84 is fixedly connected with the second ram 85 in the fourth sliding groove 86, the second partition 84 is slidably engaged with the fourth slide slot 86.

Beneficially, a third limiting groove 81 is disposed at a symmetrical position of the fourth sliding groove 86 on the left end wall of the diversion cavity 3, a second movable block 82 is slidably fitted in the third limiting groove 81, and the second movable block 82 is connected to the third limiting groove 81 through a third spring 83.

In the initial state, the first motor 28 and the second motor 29 stop rotating;

when the dye crusher starts to work, dye is poured into the material cylinder 13 from the material inlet 1, the material cylinder 13 moves downwards, the first friction disc 78 contacts with the second friction disc 79, the first motor 28 rotates, the first transmission shaft 9 drives the sixth helical gear 9 and the first helical gear 16 to rotate, the first helical gear 16 drives the main transmission shaft 22 to rotate, the main transmission shaft 22 drives the impeller 21 to rotate, the main transmission shaft 22 drives the first friction disc 78 and the third gear 76 to rotate, the first friction disc 78 drives the material cylinder 13 to rotate through the second friction disc 79, the third gear 76 drives the fourth rotating shaft 63 to rotate through the second gear 73, the fourth rotating shaft 63 drives the cutter 15 to rotate, dye is crushed, and the dye flows into the shunting cavity 3 through the filter plate 14 after being crushed, the second motor 29 rotates, the second transmission shaft 28 drives the first belt pulley 27 to rotate, the first belt pulley 27 drives the second belt pulley 31 to rotate through the first transmission belt 26, the second belt pulley 31 drives the fourth transmission shaft 43 to rotate through the second spline sleeve 42, the fourth transmission shaft 43 drives the third bevel gear 37 to rotate through the second bevel gear 32, the third bevel gear 37 drives the second bevel gear 39 to rotate through the third transmission shaft 40, and the water pumping cavity 38 adds water to the stirring cavity 20.

When the dye reaches a certain concentration, the push rod 34 is pushed, the push rod 34 drives the fourth transmission shaft 43 to move, the second helical gear 32 stops rotating, the water pumping cavity 38 stops working, the first friction block 44 contacts with the second friction block 45, the fourth helical gear 47 drives the fourth pulley 53 and the fifth helical gear 54 to rotate, the fourth pulley 53 drives the worm 50 and the worm gear 49 to rotate by means of the third pulley 46, the worm gear 49 drives the partition plate 25 to move by means of the screw 48, the liquid in the stirring cavity 20 flows out through the water outlet 11, the fifth helical gear 54 drives the eighth helical gear 58 to rotate by means of the seventh helical gear 56, the eighth helical gear 58 drives the rack 60 to move by means of the first gear 59, the left end of the rack 60 extends into the first chute 8 to push the first push rod 6 to move, the second top rod 85 drives the second partition 84 to move and extend into the third limiting groove 81.

After the drainage is finished, the second motor 29 is turned over, the partition plate 25 is closed, and the rack 60 and the second partition plate 84 are restored to the original state.

And when the work is finished, the first motor 18 and the second motor 29 are turned off.

The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.

Claims

1. A dye crushing device comprises a machine body, wherein a shunting cavity is arranged in the machine body, a feed inlet communicated with the outside is formed in the top wall of the shunting cavity, a fixed block fixedly connected with front and rear end walls is arranged in the shunting cavity, a third groove with an upward opening is formed in the upper end wall of the fixed block, an auxiliary transmission device is arranged in the third groove, a first movable cavity is arranged on the lower side of the third groove of the fixed block, a first motor is fixedly arranged on the left end wall of the first movable cavity, the first motor is in power connection with a first transmission shaft, a sixth helical gear is fixedly arranged on the first transmission shaft and meshed with the first helical gear, the first helical gear is fixedly arranged on a main transmission shaft, the main transmission shaft is rotationally connected with the upper and lower end walls of the first movable cavity, and rotary grooves are symmetrically formed in the left and right sides of the third groove of the top, the rotary groove is characterized in that first limiting grooves are arranged in the left side wall and the right side wall of the rotary groove, the first limiting grooves are connected with second limiting grooves, movable rods are arranged in the second limiting grooves in a sliding fit mode, second springs connected with the movable rods are fixedly arranged on the bottom walls of the second limiting grooves, fifth rotating shafts are rotatably arranged on the movable rods, rollers are fixedly arranged on the fifth rotating shafts, material cylinders are arranged on the rollers, annular grooves are formed in the top walls of the shunting cavities, the upper ends of the rollers extend into the annular grooves, filter plates are fixedly arranged on the walls of the rollers, stirring cavities are formed in the lower ends of the fixed blocks, the lower ends of main transmission shafts extend into the stirring cavities to be rotatably connected with the stirring bottom walls, impellers are fixedly connected with the main transmission shafts in the stirring cavities, first grooves are formed in the right end walls of the stirring cavities, discharge ports are connected to the right sides of the first, a main transmission device is arranged in the first movable cavity.

2. The dye reducing apparatus according to claim 1, wherein: the auxiliary transmission device comprises a third groove, the upper end of the auxiliary transmission device extends into the third groove and is in rotating connection with the bottom wall of the third groove, the main transmission shaft is fixedly connected with a first friction disc and a third gear in the third groove, the left side and the right side of the third gear are symmetrically meshed with a second gear, the second gear is fixedly installed in a fourth rotating shaft, the fourth rotating shaft is rotatably installed on a movable plate, the movable plate is in sliding fit with the third groove, a through hole is formed in the movable plate, the main transmission shaft penetrates through the through hole, the bottom wall of the charging barrel is fixedly installed with a second friction disc in the third groove, a spline sleeve is connected to the fourth rotating shaft through a spline, the spline sleeve is rotatably installed on the bottom wall of the charging barrel, and a cutter is fixedly installed in the charging barrel at the upper end of the.

3. The dye reducing apparatus according to claim 1, wherein: the main transmission device comprises a second motor fixedly arranged on the upper end wall of the first movable cavity, the second motor is in power connection with a second transmission shaft, a first belt pulley is fixedly arranged on the second transmission shaft, the first belt pulley is connected with a second belt pulley through a first conveyor belt, the second belt pulley is fixedly arranged on a second spline sleeve, a second movable cavity is arranged on the left side of the first movable cavity, the second spline sleeve is rotatably arranged on a wall body between the first movable cavity and the second movable cavity, a fourth transmission shaft is in spline connection in the second spline sleeve, a push rod is rotatably connected on the right side of the third transmission shaft, the push rod is in sliding fit with the right end wall of the first movable cavity and penetrates through the machine body, a round platform is fixedly arranged on the right side of the third transmission shaft, a second helical gear is in sliding fit with the round platform, and a T-shaped annular groove is arranged on the right end wall of the second helical gear, a fixed rod is rotationally matched in the T-shaped ring groove, and the right end of the fixed rod is fixedly arranged on the right end wall of the first movable cavity.

4. A dye reducing apparatus according to claim 3, wherein: first activity chamber downside is equipped with the chamber of drawing water, the chamber right side of drawing water is equipped with the water inlet, the chamber left side of drawing water be equipped with the delivery port that the stirring chamber is connected, it installs the third transmission shaft to rotate on the chamber bottom wall to draw water, fixed mounting has the second helical gear on the third transmission shaft, third transmission shaft upper end stretches into first activity chamber fixedly connected with third helical gear, the meshing of third helical gear upper end the second helical gear.

5. A dye reducing apparatus according to claim 3, wherein: the left end of the fourth transmission shaft extends into the second transmission cavity and is fixedly connected with a first friction block, the left end wall of the second movable cavity is rotatably provided with a first rotating shaft, a fourth belt wheel and a fourth helical gear are fixedly arranged on the first rotating shaft, a second friction block is fixedly arranged on the right end face of the fourth helical gear, a worm is rotatably arranged on the left end wall of the second movable cavity, a third belt wheel is fixedly arranged on the worm, the third belt wheel is connected with the fourth belt wheel through a second transmission belt, the worm is meshed with a worm wheel, the worm wheel is fixedly arranged on the screw rod, a second sliding groove is arranged at the lower side of the second movable cavity, the lower end of the screw rod extends into the second sliding groove and is matched with a wall body between the second sliding groove and the second movable cavity in a rotating way, the screw is in threaded connection with a partition plate in sliding fit with the second sliding groove, and the second sliding groove penetrates through the groove.

6. The dye reducing apparatus according to claim 5, wherein: the utility model discloses a gear rack, including second activity chamber, second pivot, fourth bevel gear, third spout diapire, second recess, second pivot upper end in fixedly connected with seventh bevel gear in the second recess, seventh bevel gear meshing has eighth bevel gear, eighth bevel gear fixed mounting is in the third pivot, the third pivot rotate install in end wall around the second recess, fixed mounting has first gear on the third back of the commentaries on classics, first gear upper end in third spout internal gearing has the rack, rack sliding fit the third spout.

7. The dye reducing apparatus according to claim 6, wherein: a first chute is arranged on the right end wall of the fixed block, a hydraulic cavity is arranged in the left side wall of the first chute, a first piston plate is arranged on the right side of the hydraulic cavity, a first mandril is fixedly arranged on the first piston plate, the left end of the first ejector rod extends into the first sliding groove and is in sliding fit with a wall body between the first sliding groove and the hydraulic cavity, the first top rod is connected with the left end wall of the first sliding chute in the first sliding chute through a first spring, a fourth chute with a leftward opening is arranged on the left side of the hydraulic cavity, a fourth piston plate is arranged on the left side of the hydraulic cavity, the fourth piston plate is fixedly connected with a second ejector rod which extends into the fourth sliding groove and is in sliding fit with a wall body between the fourth sliding groove and the hydraulic cavity, the second ejector rod is fixedly connected with a second partition plate in the fourth sliding groove, and the second partition plate is in sliding fit with the fourth sliding groove.

8. The dye reducing apparatus according to claim 7, wherein: the left end wall of the shunting cavity is provided with a third limiting groove at the symmetrical position of the fourth sliding groove, a second movable block is matched with the third limiting groove in a sliding mode, and the second movable block is connected with the third limiting groove through a third spring.