CN210964946U

CN210964946U - Reverse crushing mechanism of single-shaft washing powder size mixing crushing device

Info

Publication number: CN210964946U
Application number: CN201921795293.1U
Authority: CN
Inventors: 郭志敏
Original assignee: Sichuan Tongqing Nanfeng Washing Products Co ltd
Current assignee: Sichuan Tongqing Nanfeng Washing Products Co ltd
Priority date: 2019-10-24
Filing date: 2019-10-24
Publication date: 2020-07-10
Anticipated expiration: 2029-10-24

Abstract

The utility model relates to a washing powder preparation technical field, concretely relates to reverse crushing mechanism of single-axis washing powder size mixing breaker, including the rabbling mechanism, the rabbling mechanism is including differential rotating assembly, the differential oar, stirring rake and the pivot that can two-way rotation, the pivot is vertical to be set up, stirring rake and differential rotating assembly all are connected with the pivot transmission, differential rotating assembly is connected with the differential oar transmission, stirring rake horizontal fixed mounting is in the pivot, the rotatable cover of differential oar is established in the pivot, differential rotating assembly horizontal installation is between stirring rake and differential oar, the fixed cover of differential rotating assembly is established in the pivot, control the differential rotating assembly through the different direction of rotation of pivot and control the synchronous or differential rotation between stirring rake and the differential oar; synchronous rotation can increase substantially the stirring effect of equipment, reduces the time that the stirring was accomplished and consumes, can carry out crushing treatment to the solid starting material in the ground paste when the differential is rotatory for the stirring is more quick and abundant, improves work efficiency.

Description

Reverse crushing mechanism of single-shaft washing powder size mixing crushing device

Technical Field

The utility model relates to a washing powder preparation technical field, concretely relates to reverse broken mechanism of single-axis type washing powder sizing mixing breaker.

Background

The washing powder is an alkaline synthetic detergent, is a chemical preparation for washing clothes, and is invented by using borate and silicate as main raw materials in 1907 years of German Han.

The main components of the washing powder are anionic surfactant, sodium alkyl benzene sulfonate, a small amount of nonionic surfactant, and some additives, phosphate, silicate, anhydrous sodium sulphate, fluorescer, enzyme, etc. through the processes of mixing, spraying and the like, the 4A fluorite is used for replacing the phosphate at present.

The washing powder formula contains sodium dodecyl benzene sulfonate, sodium carbonate, sodium silicate, sodium tripolyphosphate, 4A zeolite, anhydrous sodium sulphate and the like, the raw materials are dispersed in water to prepare viscous slurry in the production process, the viscous slurry is simply treated and then conveyed to a slurry spray gun through a high-pressure pump to be sprayed in a high tower, the base powder of the washing powder can be obtained after the vaporous slurry is dried by hot air, and the appearance, the surface density and the proportion of unqualified products of the washing powder are directly influenced.

In the slurry mixing process, solid raw materials and liquid raw materials need to be mixed and stirred in proportion to finally prepare viscous slurry, in the actual production process, the mixing of the solid raw materials and the liquid raw materials needs a longer time, solid particles which are not completely reacted in finished product slurry can remain in the slurry to influence the product quality, when the slurry is discharged, the viscous slurry is easily adhered to the barrel wall of a slurry mixing barrel to cause insufficient discharging, the discharging efficiency is low due to the viscous slurry,

therefore, there is a need to design a reverse crushing mechanism of a single-shaft washing powder size mixing crushing device, which can improve the stirring efficiency, can crush solid raw materials, and can rotate synchronously or at different speeds during stirring.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a reverse crushing mechanism of a single-shaft washing powder size mixing and crushing device,

to achieve the purpose, the utility model adopts the following technical proposal:

the utility model provides a single-axis washing powder size mixing breaker's reverse broken mechanism, including rabbling mechanism, the rabbling mechanism is including differential rotating assembly, the differential oar, stirring rake and the pivot that can two-way rotation, the vertical setting of pivot, stirring rake and differential rotating assembly all are connected with the pivot transmission, differential rotating assembly is connected with the differential oar transmission, the horizontal fixed mounting of stirring rake is in the pivot, the rotatable cover of differential oar is established in the pivot, differential rotating assembly horizontal installation is between stirring rake and differential oar, the fixed cover of differential rotating assembly is established in the pivot.

As a preferred scheme of a reverse crushing mechanism of the single-shaft washing powder size mixing crushing device, the stirring mechanism further comprises a bidirectional rotating motor, the bidirectional rotating motor is vertically arranged right above the rotating shaft, an output shaft of the bidirectional rotating motor is vertically downward, and the output shaft of the bidirectional rotating motor is fixedly connected with the top of the rotating shaft through a coupler.

As a preferred scheme of a reverse crushing mechanism of a single-shaft washing powder size mixing crushing device, a differential rotating assembly comprises a fixing ring, a transmission ring and a transmission rod, wherein the fixing ring, the transmission ring and the transmission rod are horizontally arranged, the fixing ring is fixedly arranged on a rotating shaft, the transmission ring is sleeved above the fixing ring, the transmission rod is arranged at the top of the fixing ring, one end of the transmission rod is hinged with the top of the fixing ring, the other end of the transmission rod is in transmission connection with the transmission ring, and the bottom of the transmission ring is fixedly connected with the top of a differential paddle.

As a preferred scheme of a reverse crushing mechanism of a single-shaft washing powder size mixing crushing device, a plurality of chutes are arranged on the inner side wall of a transmission ring, the notches of the chutes are in transmission fit with one end, far away from the hinged end, of a transmission rod, the chutes are annularly distributed along the axis of the transmission ring, and the chutes are connected end to end.

As a preferred scheme of the reverse crushing mechanism of the single-shaft washing powder size mixing crushing device, three transmission rods are arranged and distributed annularly along the axis of the fixing ring.

As a preferred scheme of a reverse crushing mechanism of a single-shaft washing powder size mixing crushing device, three blades are arranged on a differential paddle and distributed annularly along the axis of the differential paddle, and each blade is provided with a plurality of through holes.

As a preferred scheme of a reverse crushing mechanism of the single-shaft washing powder size mixing crushing device, the stirring mechanism further comprises a spiral scraper and a fixed rod, the spiral scraper is vertically arranged, the fixed rod is horizontally arranged in the middle of the rotating shaft, one end of the fixed rod is fixedly sleeved on the rotating shaft, and the other end of the fixed rod is fixedly connected with a scraping wall of the spiral scraper.

As a preferred scheme of a reverse crushing mechanism of a single-shaft washing powder size mixing crushing device, two groups of stirring paddles, two groups of differential paddles and two groups of differential rotating assemblies are arranged, and the two groups of stirring paddles, the two groups of differential paddles and the two groups of differential rotating assemblies are sequentially distributed along the axial direction of a rotating shaft.

The utility model has the advantages that: the bidirectional rotating motor can drive the rotating shaft to rotate bidirectionally, and the differential rotating assembly is controlled through different rotating directions so as to control the stirring paddle and the differential paddle to rotate synchronously or in a differential manner; the stirring effect of equipment can be greatly improved during synchronous rotation, the time consumed by stirring is reduced, and solid raw materials in slurry can be subjected to crushing treatment during differential rotation, so that stirring is quicker and more sufficient, and the working efficiency is improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required to be used in the embodiments of the present invention will be briefly described below. It is obvious that the drawings described below are only some embodiments of the invention, and that for a person skilled in the art, other drawings can be obtained from these drawings without inventive effort.

Fig. 1 is a schematic perspective view of a reverse crushing mechanism of a single-shaft washing powder mixing crusher according to an embodiment of the present invention;

FIG. 2 is a schematic perspective view of a reverse crushing mechanism of a single-shaft washing powder size mixing crusher according to an embodiment of the present invention;

FIG. 3 is a front view of a reverse crushing mechanism of a single-shaft washing powder size mixing crusher according to an embodiment of the present invention;

FIG. 4 is a schematic perspective view of a first slurry mixing barrel of a reverse crushing mechanism of a single-shaft washing powder slurry mixing and crushing device according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of a second three-dimensional structure of a size mixing barrel of a reverse crushing mechanism of a single-shaft washing powder size mixing crusher according to an embodiment of the present invention;

FIG. 6 is a schematic perspective view of a vibrating blanking mechanism of a reverse crushing mechanism of a single-shaft washing powder mixing crusher according to an embodiment of the present invention;

FIG. 7 is an exploded view of a vibrating blanking mechanism of a reverse crushing mechanism of a single-shaft washing powder mixing crusher according to an embodiment of the present invention;

fig. 8 is an exploded perspective view of a feeding assembly of a reverse crushing mechanism of a single-shaft washing powder mixing crusher according to an embodiment of the present invention;

FIG. 9 is a schematic view of a three-dimensional structure of a stirring mechanism of a reverse crushing mechanism of a single-shaft washing powder mixing crusher according to an embodiment of the present invention;

FIG. 10 is a side view of FIG. 9;

fig. 11 is a schematic partial perspective view of a reverse crushing mechanism of a single-shaft washing powder size mixing crusher according to an embodiment of the present invention;

fig. 12 is a partial three-dimensional exploded view of a reverse crushing mechanism of a single-shaft washing powder mixing crusher according to an embodiment of the present invention;

fig. 13 is a schematic view of a three-dimensional structure of a differential rotation assembly of a reverse crushing mechanism of a single-shaft washing powder mixing crusher according to an embodiment of the present invention.

In the figure:

the device comprises a fixed frame 1, a size mixing barrel 2, a stirring mechanism 3, a feeding mechanism 4, a vibration blanking mechanism 5, a collecting box 6, a solid feeding hole 7, a liquid feeding hole 8, a discharging hole 9, a blanking channel 10, an elastic limiting ring 11, a first filter screen 12, a cap 13, a hinged plate 14, a first liquid feeding pipe 15, a flow meter 16, a second liquid feeding pipe 17, a vibration motor 18, a fixed seat 19, a second filter screen 20, a top block 21, a sliding groove 22, a sliding block 23, an installation limiting ring 24, a differential rotation component 25, a differential paddle 26, a stirring paddle 27, a rotating shaft 28, a bidirectional rotation motor 29, a fixed ring 30, a transmission ring 31, a transmission rod 32, a chute 33, a blade 34, a through hole 35, a spiral scraper 36 and a fixed rod 37.

Detailed Description

The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.

Wherein the showings are for the purpose of illustration only and are shown by way of illustration only and not in actual form, and are not to be construed as limiting the present patent; for a better understanding of the embodiments of the present invention, some parts of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product; it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

The same or similar reference numerals in the drawings of the embodiments of the present invention correspond to the same or similar parts; in the description of the present invention, it should be understood that if the terms "upper", "lower", "left", "right", "inner", "outer", etc. are used to indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, it is only for convenience of description and simplification of description, but it is not indicated or implied that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore, the terms describing the positional relationship in the drawings are used only for illustrative purposes and are not to be construed as limiting the present patent, and the specific meaning of the terms will be understood by those skilled in the art according to the specific circumstances.

In the description of the present invention, unless otherwise explicitly specified or limited, the term "connected" or the like, if appearing to indicate a connection relationship between the components, is to be understood broadly, for example, as being either a fixed connection, a detachable connection, or an integral part; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or may be connected through one or more other components or may be in an interactive relationship with one another. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Before introducing a reverse crushing mechanism of a single-shaft washing powder size mixing crushing device, the single-shaft washing powder size mixing crushing device is explained as follows: as shown in fig. 1 to 8, it comprises a fixed frame 1, a size mixing barrel 2, a stirring mechanism 3, a feeding mechanism 4, a vibration blanking mechanism 5 and a collecting box 6, wherein the fixed frame 1 is vertically arranged, the size mixing barrel 2 is vertically arranged on the fixed frame 1, the stirring mechanism 3 is vertically arranged inside the size mixing barrel 2, the feeding mechanism 4 is fixedly arranged at the top of the size mixing barrel 2, the vibration blanking mechanism 5 is vertically arranged at the bottom of the size mixing barrel 2, the collecting box 6 is horizontally arranged right below the size mixing barrel 2,

the top of the size mixing barrel 2 is provided with a solid feeding hole 7 and a liquid feeding hole 8, the feeding mechanism 4 is fixedly connected with the size mixing barrel 2 through the solid feeding hole 7 and the liquid feeding hole 8, the bottom of the size mixing barrel 2 is provided with a discharging hole 9, and the top of the vibrating blanking mechanism 5 is elastically connected with the size mixing barrel 2 through the discharging hole 9.

Vibration unloading mechanism 5 is including the unloading passageway 10 that can vibrate, elasticity spacing ring 11, first filter screen 12 and cap 13, the vertical setting of unloading passageway 10 is in the bottom of size mixing bucket 2, the top and the discharge gate 9 of unloading passageway 10 are connected, the top in the unloading passageway 10 outside is established to the fixed level cover of elasticity spacing ring 11, the horizontal fixed mounting of first filter screen 12 is at the inboard top of unloading passageway 10, cap 13 level sets up the bottom at unloading passageway 10, end threaded connection under the inboard of cap 13 and the outside of unloading passageway 10.

The feeding mechanism 4 comprises a hinged plate 14 and a first liquid feeding pipe 15, the hinged plate 14 is arranged right above the solid feeding hole 7, one side of the hinged plate 14 is hinged with the top of the size mixing barrel 2, the first liquid feeding pipe 15 is vertically arranged above the liquid feeding hole 8, and the bottom of the first liquid feeding pipe 15 is fixedly connected with the outer edge of the liquid feeding hole 8. When the manual work is carried out the material loading, upwards turn over articulated slab 14 to open solid feed inlet 7, in the manual work added solid raw materials and made the milk mixing bucket 2, the manual work added liquid raw materials from first liquid pan feeding pipe 15, in liquid feed inlet 8 flowed into the milk mixing bucket 2, accomplished the material loading process.

The feeding mechanism 4 further comprises a flow meter 16 and two second liquid feeding pipes 17, the flow meter 16 is fixedly installed at the top of the first liquid feeding pipe 15, the second liquid feeding pipes 17 are vertically and fixedly installed at the top of the flow meter 16, and the flow meter 16 is respectively communicated with the first liquid feeding pipe 15 and the second liquid feeding pipes 17. Different kinds of liquid raw materials need to be added during size mixing, the independent addition of different kinds of liquid raw materials can be realized through a plurality of second liquid pan feeding pipes 17, the liquid raw materials that add can be measured to flowmeter 16 to accomplish the material loading process that different kinds of liquid raw materials ration were added alone.

Vibration unloading mechanism 5 is still including vibrating motor 18 and fixing base 19, and fixing base 19 is fixed to be set up on the lateral wall of unloading passageway 10, and vibrating motor 18 fixed mounting is in the one side that unloading passageway 10 was kept away from to fixing base 19, and vibrating motor 18 is connected with unloading passageway 10 transmission. When the equipment is used for blanking, the vibration motor 18 works, the vibration motor 18 drives the blanking channel 10 to vibrate, so that the vibration crushing screening work is completed, and the fixed seat 19 is used for fixedly installing the vibration motor 18 on the blanking channel 10.

The vibration blanking mechanism 5 further comprises a second filter screen 20, the second filter screen 20 is horizontally arranged in the blanking channel 10 in a sliding mode, and the meshes of the second filter screen 20 are smaller than those of the first filter screen 12. When vibration unloading mechanism 5 during operation, great broken result falls into second filter screen 20 downwards from first filter screen 12, because the mesh of second filter screen 20 is less, thereby it is lived it, it falls into the receipts workbin downwards again to shatter through continuous vibration, realize the function of vibration unloading at last, when equipment is stirring the size mixing, second filter screen 20 is in the highest position, the top of second filter screen 20 conflicts with the bottom of first filter screen 12, prevent that the raw materials in the stirring from falling into between first filter screen 12 and the second filter screen 20, influence the production quality, when equipment is when the unloading, second filter screen 20 slides to the lowest, begin vibration unloading work.

The top of cap 13 is equipped with columniform kicking block 21, vertically is equipped with spout 22 on the inner wall of unloading passageway 10, is equipped with on the outer edge of second filter screen 20 with spout 22 sliding fit's slider 23. When the cap 13 is covered, the top block 21 jacks up the second filter screen 20 until the second filter screen 20 is attached to the first filter screen 12, and the second filter screen 20 is matched with the sliding block 23 through the sliding groove 22 to realize sliding connection with the blanking channel 10.

The top of mount 1 is equipped with the collar, is equipped with installation spacing ring 24 on the lateral wall of mixing of milk bucket 2, and mixing of milk bucket 2 is through installation spacing ring 24 and collar and mount 1 fixed connection. The cooperation of collar and installation spacing ring 24 has realized the installation of mixing bucket 2 on mount 1, has guaranteed the normal work of equipment.

Referring to fig. 9 to 13, the reverse crushing mechanism of the single-shaft washing powder size mixing crushing device comprises a stirring mechanism 3, wherein the stirring mechanism 3 comprises a differential rotation assembly 25, a differential paddle 26, a stirring paddle 27 and a rotating shaft 28 capable of rotating in two directions, the rotating shaft 28 is vertically arranged, the stirring paddle 27 and the differential rotation assembly 25 are in transmission connection with the rotating shaft 28, the differential rotation assembly 25 is in transmission connection with the differential paddle 26, the stirring paddle 27 is horizontally and fixedly installed on the rotating shaft 28, the differential paddle 26 is rotatably sleeved on the rotating shaft 28, the differential rotation assembly 25 is horizontally installed between the stirring paddle 27 and the differential paddle 26, and the differential rotation assembly 25 is fixedly sleeved on the rotating shaft 28. When the washing powder raw pulp needs to be stirred and crushed, the stirring mechanism 3 works, the rotating shaft 28 starts to rotate to drive the stirring paddle 27 and the differential rotation component 25 to rotate, the differential rotation component 25 drives the differential paddle 26 to rotate, so that the washing powder slurry is stirred and crushed, and finally the washing powder is manufactured, during stirring, the differential speed rotator controls the differential speed paddle 26 and the rotating shaft 28 to synchronously rotate, so that the stirring paddle 27 and the differential speed paddle 26 synchronously rotate, the stirring is more sufficient, the stirring effect is improved, when the solid raw material is required to be crushed, the rotating shaft 28 rotates reversely, the rotating shaft 28 drives the stirring paddle 27 and the differential rotating assembly 25 to rotate, the transmission effect of the differential rotating assembly 25 on the differential paddle 26 is greatly reduced, the differential paddle 26 rotates slowly, and a differential speed is formed between the differential paddle 26 and the stirring paddle 27, so that the crushing treatment of the washing powder solid raw material and large particle matters in slurry is realized.

The stirring mechanism 3 further comprises a bidirectional rotating motor 29, the bidirectional rotating motor 29 is vertically arranged right above the rotating shaft 28, an output shaft of the bidirectional rotating motor 29 is vertically downward, and the output shaft of the bidirectional rotating motor 29 is fixedly connected with the top of the rotating shaft 28 through a coupler. When the stirring mechanism 3 works, the output shaft of the bidirectional rotating motor 29 drives the rotating shaft 28 to rotate, so that a power source is provided for the whole device, when stirring is needed, the output shaft of the bidirectional rotating motor 29 rotates forwards, the differential rotating assembly 25 fixedly mounted on the rotating shaft 28 drives the differential paddle 26 and the rotating shaft 28 to rotate synchronously, so that the bidirectional rotating motor 27 rotates synchronously, when crushing is needed, the bidirectional rotating motor 29 rotates backwards, the differential rotating assembly 25 reduces the transmission effect on the differential paddle 26, differential rotation is formed between the differential paddle 26 and the stirring paddle 27, and therefore large particles in washing powder solid raw materials and size mixing products are crushed.

Differential rotating assembly 25 is including solid fixed ring 30, transmission ring 31 and transfer line 32, gu fixed ring 30, the equal level setting of transmission ring 31 and transfer line 32, gu fixed ring 30 fixed mounting is in pivot 28, the transmission ring 31 cover is established in solid fixed ring 30 top, transfer line 32 sets up at solid fixed ring 30 top, the one end of transfer line 32 is articulated with solid fixed ring 30's top, the other end and the transmission ring 31 transmission of transfer line 32 are connected, the bottom of transmission ring 31 and the top fixed connection of differential oar 26. When the rotating shaft 28 rotates forwards, the fixing ring 30 rotates synchronously with the rotating shaft 28, the transmission rod 32 on the fixing ring 30 rotates together with the fixing ring 30, one end of the transmission rod 32, which is far away from the hinge, deflects outwards under the action of centrifugal force, the outer side wall of the transmission rod 32 props against the inner wall of the transmission ring 31 when rotating, so as to drive the transmission ring 31 to rotate synchronously, further to enable the differential paddle 26 and the stirring paddle 27 which are fixedly connected with the transmission ring 31 to rotate synchronously, so as to achieve better stirring effect, when the rotating shaft rotates reversely, the fixing ring 30 rotates synchronously with the rotating shaft 28, one end of the transmission rod 32, which is far away from the hinge, deflects outwards under the action of centrifugal force, the transmission capacity of the outer side wall of the transmission rod 32 to the inner wall of the transmission ring 31 is greatly reduced when rotating, so as to enable the differential paddle 26 to rotate slowly, further, convection current is formed inside the equipment, and large particles are crushed.

Be equipped with a plurality of chute 33 on the inside wall of drive ring 31, the notch of chute 33 and the one end transmission cooperation of keeping away from the hinged end of transfer line 32, a plurality of chute 33 is along drive ring 31 axis annular distribution to end between chute 33 and the chute 33. When the transmission rod 32 rotates, one end of the transmission rod 32, which is far away from the hinged part, is attached to the groove wall of the chute 33, when the rotating shaft 28 rotates forwards, the transmission rod 32 props against the groove wall of the chute 33 and enables the transmission ring 31 to rotate synchronously along with the transmission rod 32, and when the rotating shaft 28 rotates backwards, the rod wall of the transmission rod 32 slides backwards along the groove wall of the chute 33, so that the transmission capacity of the transmission rod 32 to the transmission ring 31 is greatly reduced, and further, the differential rotation effect between the differential paddle 26 and the stirring paddle 27 is realized.

The transmission rods 32 are provided in three, three transmission rods 32 being annularly distributed along the axis of the stationary ring 30. The three transmission rods 32 can achieve a better transmission effect, and ensure the synchronous rotation effect of the transmission ring 31 and the rotating shaft 28 when the rotating shaft 28 rotates forwards.

The differential paddle 26 is provided with three blades 34, the three blades 34 are distributed annularly along the axis of the differential paddle 26, and each blade 34 is provided with a plurality of through holes 35. When differential oar 26 rotated, the blade 34 on the differential oar 26 was rotatory, and through-hole 35 on the blade 34 can promote the crushing effect to the particulate matter greatly, reduced broken time, improved work efficiency.

The stirring mechanism 3 further comprises a spiral scraper 36 and a fixing rod 37, the spiral scraper 36 is vertically arranged, the fixing rod 37 is horizontally arranged in the middle of the rotating shaft 28, one end of the fixing rod 37 is fixedly sleeved on the rotating shaft 28, and the other end of the fixing rod 37 is fixedly connected with the scraping wall of the spiral scraper 36. The spiral scraper 36 realizes synchronous rotation with the rotating shaft 28 through the fixing rod 37, scrapes off the bucket wall in the rotating process of the rotating shaft 28, prevents products of size mixing from remaining on the bucket wall and being difficult to clear, and in the reversing process of the rotating shaft 28, differential rotation is formed between the spiral scraper 36 and the differential paddle 26, so that the crushing efficiency is improved.

The stirring paddles 27, the differential paddles 26 and the differential rotating assembly 25 are provided with two groups, and the two groups of stirring paddles 27, the differential paddles 26 and the differential rotating assembly 25 are sequentially distributed along the axial direction of the rotating shaft 28. The two groups of stirring paddles 27, the differential paddles 26 and the differential rotating assembly 25 are arranged, so that the stirring capacity and the crushing capacity of the equipment are greatly improved, the slurry mixing materials in the barrel can be fully stirred and crushed, and the working efficiency of the equipment is improved.

The utility model discloses a theory of operation: before the equipment works, manually adding fixed raw materials into a solid feed inlet 7 of a box through a feeding mechanism 4, adding liquid raw materials into a liquid feed inlet 8, after the raw materials are added into a size mixing barrel 2, stirring and size mixing the raw materials through a stirring mechanism 3 and smashing size mixing products, discharging the finally obtained product downwards through a discharge port 9 through a vibration discharging mechanism 5, stopping the larger size mixing product in the size mixing barrel 2 through a first filter screen 12 by the vibration discharging mechanism 5, smashing the product by the stirring mechanism 3 and then discharging, vibrating and decomposing the larger solid particles on the first filter screen 12 into smaller particles through the vibration of a discharging channel 10, then falling from the discharging channel 10 and finally falling into a collecting box 6, when the size mixing barrel 2 is stirring and size mixing, a cap 13 is in threaded connection with the lower end of the discharging channel 10, after the product is crushed, opening the cap 13, and finishing the collecting process after the product falls, in the vibration process of the blanking channel 10, the elastic limiting ring 11 can ensure that the blanking channel 10 cannot deviate or fall off when vibrating. When the washing powder raw pulp needs to be stirred and crushed, the stirring mechanism 3 works, the rotating shaft 28 starts to rotate to drive the stirring paddle 27 and the differential rotation component 25 to rotate, the differential rotation component 25 drives the differential paddle 26 to rotate, so that the washing powder slurry is stirred and crushed, and finally the washing powder is manufactured, during stirring, the differential speed rotator controls the differential speed paddle 26 and the rotating shaft 28 to synchronously rotate, so that the stirring paddle 27 and the differential speed paddle 26 synchronously rotate, the stirring is more sufficient, the stirring effect is improved, when the solid raw material is required to be crushed, the rotating shaft 28 rotates reversely, the rotating shaft 28 drives the stirring paddle 27 and the differential rotating assembly 25 to rotate, the transmission effect of the differential rotating assembly 25 on the differential paddle 26 is greatly reduced, the differential paddle 26 rotates slowly, and a differential speed is formed between the differential paddle 26 and the stirring paddle 27, so that the crushing treatment of the washing powder solid raw material and large particle matters in slurry is realized. When the stirring mechanism 3 works, the output shaft of the bidirectional rotating motor 29 drives the rotating shaft 28 to rotate, so that a power source is provided for the whole device, when stirring is needed, the output shaft of the bidirectional rotating motor 29 rotates forwards, the differential rotating assembly 25 fixedly mounted on the rotating shaft 28 drives the differential paddle 26 and the rotating shaft 28 to rotate synchronously, so that the bidirectional rotating motor 27 rotates synchronously, when crushing is needed, the bidirectional rotating motor 29 rotates backwards, the differential rotating assembly 25 reduces the transmission effect on the differential paddle 26, differential rotation is formed between the differential paddle 26 and the stirring paddle 27, and therefore large particles in washing powder solid raw materials and size mixing products are crushed. When the rotating shaft 28 rotates forwards, the fixing ring 30 rotates synchronously with the rotating shaft 28, the transmission rod 32 on the fixing ring 30 rotates together with the fixing ring 30, one end of the transmission rod 32, which is far away from the hinge, deflects outwards under the action of centrifugal force, the outer side wall of the transmission rod 32 props against the inner wall of the transmission ring 31 when rotating, so as to drive the transmission ring 31 to rotate synchronously, further to enable the differential paddle 26 and the stirring paddle 27 which are fixedly connected with the transmission ring 31 to rotate synchronously, so as to achieve better stirring effect, when the rotating shaft rotates reversely, the fixing ring 30 rotates synchronously with the rotating shaft 28, one end of the transmission rod 32, which is far away from the hinge, deflects outwards under the action of centrifugal force, the transmission capacity of the outer side wall of the transmission rod 32 to the inner wall of the transmission ring 31 is greatly reduced when rotating, so as to enable the differential paddle 26 to rotate slowly, further, convection current is formed inside the equipment, and large particles are crushed. When the transmission rod 32 rotates, one end of the transmission rod 32, which is far away from the hinged part, is attached to the groove wall of the chute 33, when the rotating shaft 28 rotates forwards, the transmission rod 32 props against the groove wall of the chute 33 and enables the transmission ring 31 to rotate synchronously along with the transmission rod 32, and when the rotating shaft 28 rotates backwards, the rod wall of the transmission rod 32 slides backwards along the groove wall of the chute 33, so that the transmission capacity of the transmission rod 32 to the transmission ring 31 is greatly reduced, and further, the differential rotation effect between the differential paddle 26 and the stirring paddle 27 is realized. The three transmission rods 32 can achieve a better transmission effect, and ensure the synchronous rotation effect of the transmission ring 31 and the rotating shaft 28 when the rotating shaft 28 rotates forwards. When differential oar 26 rotated, the blade 34 on the differential oar 26 was rotatory, and through-hole 35 on the blade 34 can promote the crushing effect to the particulate matter greatly, reduced broken time, improved work efficiency. The spiral scraper 36 realizes synchronous rotation with the rotating shaft 28 through the fixing rod 37, scrapes off the bucket wall in the rotating process of the rotating shaft 28, prevents products of size mixing from remaining on the bucket wall and being difficult to clear, and in the reversing process of the rotating shaft 28, differential rotation is formed between the spiral scraper 36 and the differential paddle 26, so that the crushing efficiency is improved. The two groups of stirring paddles 27, the differential paddles 26 and the differential rotating assembly 25 are arranged, so that the stirring capacity and the crushing capacity of the equipment are greatly improved, the slurry mixing materials in the barrel can be fully stirred and crushed, and the working efficiency of the equipment is improved.

It should be understood that the above-described embodiments are merely illustrative of the preferred embodiments of the present invention and the technical principles thereof. It will be understood by those skilled in the art that various modifications, equivalents, changes, and the like can be made to the present invention. However, these modifications are within the scope of the present invention as long as they do not depart from the spirit of the present invention. In addition, certain terms used in the specification and claims of the present application are not limiting, but are used merely for convenience of description.

Claims

1. The utility model provides a single-axis washing powder size mixing breaker's reverse broken mechanism, a serial communication port, including rabbling mechanism (3), rabbling mechanism (3) are including differential rotating assembly (25), differential oar (26), stirring rake (27) and pivot (28) that can two-way rotation, pivot (28) are vertical to be set up, stirring rake (27) and differential rotating assembly (25) all are connected with pivot (28) transmission, differential rotating assembly (25) are connected with differential oar (26) transmission, stirring rake (27) horizontal fixed mounting is on pivot (28), the rotatable cover of differential oar (26) is established on pivot (28), differential rotating assembly (25) horizontal installation is between stirring rake (27) and differential oar (26), the fixed cover of differential rotating assembly (25) is established on pivot (28).

2. The reverse crushing mechanism of the single-shaft washing powder size mixing crushing device according to claim 1, wherein the stirring mechanism (3) further comprises a bidirectional rotating motor (29), the bidirectional rotating motor (29) is vertically arranged right above the rotating shaft (28), an output shaft of the bidirectional rotating motor (29) is vertically downward, and the output shaft of the bidirectional rotating motor (29) is fixedly connected with the top of the rotating shaft (28) through a coupler.

3. The reverse crushing mechanism of the single-shaft washing powder size mixing crushing device according to claim 1, wherein the differential rotating assembly (25) comprises a fixing ring (30), a transmission ring (31) and a transmission rod (32), the fixing ring (30), the transmission ring (31) and the transmission rod (32) are horizontally arranged, the fixing ring (30) is fixedly installed on the rotating shaft (28), the transmission ring (31) is sleeved on the fixing ring (30), the transmission rod (32) is arranged at the top of the fixing ring (30), one end of the transmission rod (32) is hinged to the top of the fixing ring (30), the other end of the transmission rod (32) is in transmission connection with the transmission ring (31), and the bottom of the transmission ring (31) is fixedly connected with the top of the differential paddle (26).

4. The reverse crushing mechanism of the single-shaft washing powder mixing crushing device of claim 3, wherein the inner side wall of the transmission ring (31) is provided with a plurality of chutes (33), the notches of the chutes (33) are in transmission fit with one end of the transmission rod (32) far away from the hinged end, the plurality of chutes (33) are annularly distributed along the axis of the transmission ring (31), and the chutes (33) are connected end to end with the chutes (33).

5. The reverse crushing mechanism of the single-shaft washing powder size mixing crushing device according to claim 3, wherein three transmission rods (32) are provided, and the three transmission rods (32) are annularly distributed along the axis of the fixed ring (30).

6. The reverse crushing mechanism of the single-shaft washing powder mixing and crushing device of claim 1, wherein the differential paddle (26) is provided with three blades (34), the three blades (34) are annularly distributed along the axis of the differential paddle (26), and each blade (34) is provided with a plurality of through holes (35).

7. The reverse crushing mechanism of the single-shaft washing powder size mixing crushing device according to claim 1, wherein the stirring mechanism (3) further comprises a spiral scraper (36) and a fixing rod (37), the spiral scraper (36) is vertically arranged, the fixing rod (37) is horizontally arranged in the middle of the rotating shaft (28), one end of the fixing rod (37) is fixedly sleeved on the rotating shaft (28), and the other end of the fixing rod (37) is fixedly connected with the scraping wall of the spiral scraper (36).

8. The reverse crushing mechanism of the single-shaft washing powder mixing crushing device according to claim 1, wherein two groups of stirring paddles (27), two groups of differential paddles (26) and two groups of differential rotating assemblies (25) are arranged, and the two groups of stirring paddles (27), the two groups of differential paddles (26) and the two groups of differential rotating assemblies (25) are sequentially distributed along the axial direction of the rotating shaft (28).