CN117839490A - Vortex spinning core spun yarn raw material mixing device - Google Patents

Abstract

The invention relates to the technical field of vortex spinning, in particular to a vortex spinning core-spun yarn raw material mixing device, which comprises a shell mechanism, a driving mechanism, a stirring mechanism and a wall scraping mechanism, wherein the shell mechanism comprises a stirring shell and two feeding holes, a stirring cavity is formed in the stirring shell, two symmetrically arranged feeding grooves are formed in the top of the stirring shell, raw materials near the side wall of the stirring cavity are moved to the middle part through an inner mixing component and an outer mixing component, so that the raw materials near the outside and near a stirring main shaft in the stirring cavity can be fully mixed, a part of raw materials can float upwards for a certain distance through rapid stirring of a plurality of stirring components, the raw materials attached to the side wall of the stirring cavity can be scraped through rotation of the wall scraping rotating component, the raw materials are prevented from being insufficiently mixed, the mixing is realized through rotation of the stirring component and the inner mixing component and the outer mixing component, and the mixing efficiency is improved.

Description

Vortex spinning core spun yarn raw material mixing device

Technical Field

The invention relates to the technical field of vortex spinning, in particular to a vortex spinning core-spun yarn raw material mixing device.

Background

The spinning of vortex spinning is that the sliver after finishing drawing is fed into the drawing device, the fiber bundle after drawing by the roller drawing device is output from the front roller jaw, the fiber bundle enters the spinning nozzle along the spiral fiber guiding channel under the action of the axial air flow at the inlet of the spinning nozzle, the needle-shaped twisting-resisting piece is arranged at the outlet of the spiral fiber guiding channel, the fiber bundle is bent at the needle part, so that the fiber bundle is kept in a state of not adding twist and is led into the vortex chamber, the front end of the fiber bundle is drawn into the yarn channel in the spindle under the dragging action of the formed yarn and twisted into the newly formed yarn to form a yarn core, the raw materials are required to be fully mixed when vortex spinning is carried out, and the raw material mixing device refers to a device for fully mixing the raw materials with different types and different proportions. The existing raw material mixing device has low mixing efficiency and poor mixing effect.

Disclosure of Invention

Based on this, it is necessary to provide a device for mixing raw materials of vortex spun core yarn, so as to solve at least one technical problem set forth in the above background art.

In order to achieve the above purpose, the present invention provides the following technical solutions:

the utility model provides a vortex spins covering yarn raw materials mixing arrangement, includes casing mechanism, actuating mechanism, rabbling mechanism and scrapes wall mechanism, casing mechanism includes stirring casing and two feed inlets, stirring cavity has been seted up to the inside stirring casing, two symmetrical feed tanks that set up have been seted up at stirring casing's top, and two the feed tank all communicates with stirring cavity, two feed inlets are fixed mounting respectively in the top of two feed tanks, actuating mechanism fixed mounting is in stirring casing's top, stirring mechanism includes stirring subassembly and the inside and outside mixed subassembly of a plurality of, stirring subassembly fixed mounting is in actuating mechanism's bottom, just stirring subassembly's bottom runs through stirring casing and extends to stirring cavity's bottom, a plurality of inside and outside mixed subassembly is installed on stirring subassembly's lateral wall, and a plurality of inside and outside mixed subassembly all is located stirring cavity, scrape the wall mechanism and rotate and install in stirring cavity's bottom.

As a further improvement of the invention, the driving mechanism comprises a driving installation frame, a driving motor, a driving wheel and a driving belt, wherein the driving installation frame is fixedly arranged at the top of the stirring shell, the driving installation frame is positioned between two feeding holes, the driving motor is fixedly arranged on one side wall of the driving installation frame, the driving wheel is rotatably arranged at the top of the driving installation frame, and the driving belt is sleeved on the driving wheel and the output shaft of the driving motor.

As a further improvement of the invention, the stirring assembly comprises a stirring main shaft and a plurality of stirring pieces, wherein the top of the stirring main shaft is fixedly arranged in a driving wheel, the stirring main shaft is in rotating fit with a stirring shell, the stirring pieces are arranged on the side walls of two opposite sides of the stirring main shaft, the stirring pieces on the same side are equidistantly arranged at intervals along the vertical direction of the stirring main shaft, the stirring pieces comprise a stirring supporting shaft, a stirring adjusting plate and a wedge-shaped stirring rod, the stirring supporting shaft is fixedly arranged on the side wall of the stirring main shaft, the stirring supporting shaft and the stirring main shaft are mutually perpendicular, the stirring adjusting plate is fixedly arranged at the bottom of the stirring supporting shaft, one end of the wedge-shaped stirring rod is provided with a rotating shaft accommodating groove, the wedge-shaped stirring rod is rotationally sleeved on the stirring supporting shaft through a torsion spring, the top of the rotating adjusting groove is communicated with the rotating shaft accommodating groove, and the stirring adjusting plate is positioned in the rotating adjusting groove.

As a further improvement of the invention, the cross section of the wedge-shaped stirring rod is a right triangle, a stirring inclined plane is formed on one side wall of the wedge-shaped stirring rod, a stirring inclined plane positioned on the right side of the stirring main shaft is formed on the front side of the wedge-shaped stirring rod, a plurality of stirring inclined planes positioned on the left side of the stirring main shaft are formed on the rear side of the wedge-shaped stirring rod, an adjusting bottom surface is formed at the bottom of the wedge-shaped stirring rod, the cross section of the rotation adjusting groove is a sector, and the stirring adjusting plate is propped against one side wall of the rotation adjusting groove far away from the stirring inclined plane.

As a further improvement of the invention, a plurality of inner and outer mixing components are fixedly arranged on the side walls of two opposite sides of the stirring main shaft, a plurality of inner and outer mixing components on the same side are equidistantly arranged along the vertical direction of the stirring main shaft, each inner and outer mixing component comprises a mixing supporting rod, a mixing tension spring, a mixing telescopic rod, a mixing sliding block, a mixing piece and a balancing weight, the mixing supporting rods are fixedly arranged on the side walls of the stirring main shaft, the mixing supporting rods and the stirring supporting shaft are mutually perpendicular, a mixing sliding groove penetrating to the bottom is formed in the top of the mixing supporting rods, a mixing telescopic groove is formed in one end of the mixing sliding groove, which is close to the stirring main shaft, the mixing tension spring is fixedly arranged at one end of the mixing tension spring, which is close to the stirring main shaft, the mixing telescopic rod is slidingly arranged in the mixing telescopic groove, the mixing sliding block is fixedly arranged at one end of the mixing telescopic rod, which is far away from the stirring main shaft, the mixing sliding block is slidingly arranged in the mixing sliding groove, the mixing piece is rotationally arranged at the top of the mixing sliding block through the torsion spring, and the balancing weight is fixedly arranged at one side of the top of the mixing sliding block, which is far away from the mixing sliding block.

The wall scraping mechanism comprises a wall scraping linkage assembly and two wall scraping rotation assemblies, wherein the wall scraping linkage assembly comprises a linkage rotating shaft, a linkage rotating block, a first linkage gear, a second linkage gear and a linkage inner gear, the linkage rotating shaft is rotatably arranged at the bottom of a stirring cavity, the top of the linkage rotating shaft is fixedly connected with the bottom of a stirring main shaft, the linkage rotating block is rotatably arranged at the bottom of the stirring cavity, the bottom of the stirring main shaft penetrates through the top of the linkage rotating block, the stirring main shaft is in rotary fit with the linkage rotating block, the bottom of the linkage rotating block is provided with a gear accommodating groove, the linkage rotating shaft is positioned in the gear accommodating groove, the first linkage gear is fixedly arranged at the bottom of the linkage rotating shaft, the second linkage gear is rotatably arranged at the bottom of the stirring cavity, the second linkage gear is meshed with the first linkage gear, the inner gear is fixedly arranged at the bottom of the gear accommodating groove, the linkage inner gear is meshed with the second linkage gear, and the two wall scraping rotation assemblies are arranged on the outer side walls of the linkage rotating block and the side walls of the two side walls of the stirring cavity are arranged on the side walls of the sliding assembly.

As a further improvement of the invention, the scraping wall rotating assembly comprises a turning rotating rod, a wedge-shaped arc rod, a plurality of turning connecting shafts and a plurality of turning separating plates, wherein the turning rotating rod is fixedly arranged on the side wall of the linkage rotating block, the bottom of the turning rotating rod is attached to the bottom of the stirring cavity, the turning rotating rod is vertically arranged with the stirring main shaft, the wedge-shaped arc rod is fixedly arranged at one end of the turning rotating rod far away from the linkage rotating block, the wedge-shaped arc rod is vertically arranged with the turning rotating rod, an attaching cambered surface is formed on the side wall of one side of the wedge-shaped arc rod far away from the stirring main shaft, the attaching cambered surface is slidingly attached to the side wall of the stirring cavity, the utility model provides a stirring main shaft, including stirring main shaft, upset connecting axle, upset separating plate, screen cloth mounting groove, screen cloth mounting inslot fixed mounting has the separation net that sieves, the one side lateral wall bottom fixed mounting that the stirring main shaft was kept away from to the mixed slider has first magnetism to inhale the piece, the upset separating plate is towards one side lateral wall bottom fixed mounting of stirring main shaft has the second magnetism to inhale the piece, just the polarity of piece is inhaled with the second magnetism to first magnetism is inhaled the piece and is the same on the lateral wall of a plurality of upset connecting axle towards stirring main shaft on the lateral wall of wedge arc rod one side lateral wall equidistance interval installation along vertical direction, a plurality of upset separating plate respectively fixed mounting is in the one end of a plurality of upset connecting axle towards stirring main shaft.

As a further improvement of the invention, a vertical linkage groove is formed in the wedge-shaped arc rod, a vertical rotating shaft is rotatably arranged at the top of the vertical linkage groove, the bottom of the vertical rotating shaft is rotatably arranged at the bottom of the vertical linkage groove, one end of the turning connecting shaft, which is far away from the stirring main shaft, penetrates through the side wall of the wedge-shaped arc rod to extend into the vertical linkage groove, a turning bevel gear is fixedly arranged at one end of the turning connecting shaft, which is positioned in the vertical linkage groove, a plurality of driving bevel gears are arranged at equal intervals along the axial direction of the vertical rotating shaft, the plurality of driving bevel gears are respectively meshed with the plurality of turning bevel gears, a driven bevel gear is fixedly arranged at the bottom of the vertical rotating shaft, a driving rotating shaft is rotatably arranged at one end of the driving rotating shaft, penetrates through the side wall of the wedge-shaped arc rod to extend into the vertical linkage groove, the other end of the driving rotating shaft penetrates through the side wall of the linkage rotating block to extend into the gear accommodating groove, the driving bevel gear is fixedly arranged at one end of the driving rotating shaft, the driving bevel gear is mutually meshed with the driven bevel gear, one end of the driving rotating shaft, a driving triggering bevel gear is fixedly arranged at one end of the gear accommodating groove is fixedly provided with a driven bevel gear, the turning triggering bevel gear is fixedly arranged at the bottom of the triggering device, and is used for triggering the intermittent rotation bevel gear is arranged in the triggering device.

As a further improvement of the invention, the overturning trigger piece comprises two trigger supporting blocks and a trigger ring, wherein the two trigger supporting blocks are fixedly arranged at the bottom of the stirring cavity, the two trigger supporting blocks are respectively positioned at the front side and the rear side of the first linkage gear, the trigger ring is fixedly arranged at the tops of the two trigger supporting blocks, an arc tooth slot is formed in the top of the trigger ring, a plurality of trigger tooth blocks are convexly arranged at the top of the arc tooth slot, and the top of the trigger ring can be propped against the bottom of the trigger bevel gear, so that the trigger bevel gear cannot rotate.

As a further improvement of the invention, a discharge chute is arranged at the bottom of one side wall of the stirring shell, the discharge chute is communicated with the stirring cavity, and a rotary door is rotatably arranged on the discharge chute.

Compared with the prior art, the invention has the beneficial effects that:

1. the raw materials that will be located near stirring cavity lateral wall through rotation inside and outside mixing element removes the middle part for the stirring cavity is interior to be close to outside and be close to the raw materials of stirring main shaft all can intensive mixing, thereby improve mixing effect, the quick stirring of a plurality of stirring element lets partial raw materials come-up one section distance, scrape the rotation of wall rotation subassembly and can scrape down the raw materials that laminates in stirring cavity lateral wall, prevent that the raw materials from failing intensive mixing, the existence of upset separator plate can separate out the raw materials of partial come-up through sieving separation, further improve mixing effect, prevent raw materials gathering, drive wheel and stirring main shaft's rotation through driving motor, the rotation of rethread stirring element and inside and outside mixing element realizes mixing, scrape the rotation of wall rotation subassembly and the effect of upset separator plate and let the raw materials of laminating on stirring cavity lateral wall again intensive mixing simultaneously, thereby improve mixing efficiency.

2. Through the contained angle between stirring inclined plane and the regulation bottom surface to and the slope range of stirring inclined plane can play the effect of separating the raw materials, the raw materials is at rotatory in-process, receive stirring inclined plane's pressure and slope, a part raw materials can come up along stirring inclined plane, thereby separate with the raw materials on the regulation bottom surface, separation effect has been improved, can further improve stirring inclined plane's inclination and come-up effect through wedge puddler's rotation, the raw materials can obtain abundant mixing and dispersion, be difficult to bond together and form the dough, stirring inclined plane, adjust the cooperation of bottom surface can make the raw materials constantly mix in the stirring cavity, the raw materials is through the upward floating motion of gravity subsidence and wedge puddler, the circulation stirring of raw materials has been realized, can fully mix the raw materials, improve stirring effect, ensure the raw materials evenly mix.

3. Can drive the direction that mixes telescopic link and mixing slide block to keeping away from the stirring main shaft through mixing the bracing piece when rotatory and remove, the biggest ninety degrees flip angle of hybrid sheet simultaneously for can carry out separation and mixing on the vertical direction, further improve the effect of mixing, can produce the repulsive force when first magnetism is inhaled the piece and is close to the second magnetism and inhale the piece, thereby make mixing slide block, mix telescopic link and hybrid sheet and slide to the direction of stirring main shaft, further promote the raw materials to the middle part of stirring cavity, increased homogeneity and the sufficiency of mixing.

4. Through the cooperation of linkage pivot, linkage internal gear, linkage rotatory piece and two turnings, the raw materials of bottom can mix, avoid directly sinking in the bottom and unable intensive mixing under certain circumstances, scrape down the raw materials that will attach to stirring cavity lateral wall through the rotation of turnings, wedge arc pole and upset separator plate, avoid it to attach to the lateral wall all the time and influence the mixing effect, separate the raw materials through sieving the separation net, avoid the raw materials to condense into clusters, influence the mixing effect.

5. Through the upset of one hundred eighty degrees can be carried out in rotatory in-process to the upset separator plate, the upset can play certain stirring effect, and can make the screen surface obtain changing, can effectively avoid the problem that the separation net blockked up that sieves, guarantee the normal operation and the separation effect of device, the rotation of upset separator plate makes the second magnetism inhale the piece and is located the top, and distance between the piece is inhaled with first magnetism is farther, and the repulsion force between second magnetism inhale piece and the first magnetism inhale the piece is insufficient for overcoming centrifugal force, thereby reduced the emergence of the slip frequency and the unstable condition of mixing the slider.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present invention.

Fig. 2 is a schematic cross-sectional structure of an embodiment of the present invention.

Fig. 3 is a schematic diagram of a removing driving mechanism and a housing mechanism according to an embodiment of the invention.

Fig. 4 is a schematic cross-sectional view of a stirring member according to an embodiment of the present invention.

Fig. 5 is a schematic structural view of a part of a wall scraping linkage assembly according to an embodiment of the invention.

Fig. 6 is a schematic structural view of an internal and external mixing assembly according to an embodiment of the present invention.

Fig. 7 is a schematic cross-sectional view of an internal and external mixing assembly according to an embodiment of the present invention.

Fig. 8 is a schematic structural diagram of a flip-flop, a driving shaft and a trigger bevel gear according to an embodiment of the present invention.

Fig. 9 is a partial enlarged view at a in fig. 2.

Fig. 10 is a partial enlarged view at B in fig. 2.

In the figure: 10. a housing mechanism; 20. a driving mechanism; 30. a stirring mechanism; 40. a wall scraping mechanism; 11. a stirring housing; 12. a feed inlet; 111. a stirring cavity; 31. a stirring assembly; 32. an inner and outer mixing assembly; 21. a driving mounting frame; 22. a driving motor; 23. a driving wheel; 24. a transmission belt; 33. a stirring main shaft; 34. a stirring member; 341. a stirring support shaft; 342. a stirring adjusting plate; 343. a wedge-shaped stirring rod; 344. rotating the adjusting groove; 345. a rotating shaft accommodating groove; 346. stirring inclined planes; 347. adjusting the bottom surface; 321. a mixed support rod; 320. a hybrid tension spring; 322. a hybrid telescoping rod; 323. a mixing slide; 324. mixing the slices; 325. balancing weight; 326. a mixing sliding groove; 327. a mixing expansion tank; 50. a wall scraping linkage assembly; 60. a wall scraping rotating assembly; 51. a linkage rotating shaft; 52. a linkage rotating block; 53. a first linkage gear; 54. a second linkage gear; 55. a linked internal gear; 521. a gear housing groove; 61. turning the rotating rod; 62. a wedge-shaped arc rod; 63. turning over the connecting shaft; 64. turning over the separating plate; 620. attaching the cambered surface; 641. a screen mounting groove; 642. sieving and separating the net; 328. a first magnetic block; 643. a second magnetic block; 621. a vertical linkage groove; 622. a vertical rotating shaft; 631. overturning the bevel gear; 623. driving a bevel gear; 624. a passive bevel gear; 611. a driving rotating shaft; 612. a drive bevel gear; 613. triggering a bevel gear; 65. turning over the trigger piece; 651. triggering the supporting block; 652. triggering a circular ring; 653. arc tooth slots; 654. triggering a tooth block; 13. the door is rotated.

Detailed Description

In order that the invention may be readily understood, a more complete description of the invention will be rendered by reference to the appended drawings. The drawings illustrate preferred embodiments of the invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1 to 10, an eddy spinning core-spun yarn raw material mixing device comprises a shell mechanism 10, a driving mechanism 20, a stirring mechanism 30 and a wall scraping mechanism 40, wherein the shell mechanism 10 comprises a stirring shell 11 and two feeding ports 12, a stirring cavity 111 is formed in the stirring shell 11, two symmetrically arranged feeding grooves are formed in the top of the stirring shell 11 and are communicated with the stirring cavity 111, the two feeding ports 12 are respectively and fixedly arranged at the tops of the two feeding grooves, the driving mechanism 20 is fixedly arranged at the top of the stirring shell 11, the stirring mechanism 30 comprises a stirring assembly 31 and a plurality of inner and outer mixing assemblies 32, the stirring assembly 31 is fixedly arranged at the bottom of the driving mechanism 20, the bottom of the stirring assembly 31 penetrates through the stirring shell 11 and extends to the bottom of the stirring cavity 111, the inner and outer mixing assemblies 32 are arranged on the side wall of the stirring assembly 31, the inner and outer mixing assemblies 32 are both positioned at the stirring cavity 111, and the wall scraping mechanism 40 is rotatably arranged at the bottom of the stirring cavity 111.

Referring to fig. 1-2, the driving mechanism 20 includes a driving mounting frame 21, a driving motor 22, a driving wheel 23 and a driving belt 24, wherein the driving mounting frame 21 is fixedly mounted on the top of the stirring housing 11, the driving mounting frame 21 is located between the two feeding ports 12, the driving motor 22 is fixedly mounted on a side wall of the driving mounting frame 21, the driving wheel 23 is rotatably mounted on the top of the driving mounting frame 21, and the driving belt 24 is sleeved on the driving wheel 23 and an output shaft of the driving motor 22.

Referring to fig. 2 to 4, the stirring assembly 31 includes a stirring main shaft 33 and a plurality of stirring members 34, the top of the stirring main shaft 33 is fixedly mounted in the driving wheel 23, the stirring main shaft 33 is in running fit with the stirring housing 11, the plurality of stirring members 34 are mounted on two opposite side walls of the stirring main shaft 33, the stirring members 34 on the same side are equidistantly spaced along the vertical direction of the stirring main shaft 33, the stirring members 34 include a stirring supporting shaft 341, a stirring adjusting plate 342 and a wedge stirring rod 343, the stirring supporting shaft 341 is fixedly mounted on the side wall of the stirring main shaft 33, the stirring supporting shaft 341 and the stirring main shaft 33 are mutually perpendicular, the stirring adjusting plate 342 is fixedly mounted at the bottom of the stirring supporting shaft 341, a rotating shaft accommodating groove 345 is formed at one end of the wedge stirring rod 343, the wedge stirring rod 343 is rotatably sleeved on the stirring supporting shaft 341 through a torsion spring, a rotating adjusting groove 344 is formed in the wedge stirring rod 343, the top of the rotating adjusting groove 344 is communicated with the rotating shaft accommodating groove 345, and the stirring adjusting plate 342 is located in the adjusting groove 342.

Referring to fig. 3 to 4, the cross section of the wedge stirring rod 343 is a right triangle, a stirring inclined plane 346 is formed on a side wall of one side of the wedge stirring rod 343, a stirring inclined plane 346 on the right side of the stirring main shaft 33 is formed on the front side of the wedge stirring rod 343, a plurality of stirring inclined planes 346 on the left side of the stirring main shaft 33 are formed on the rear side of the wedge stirring rod 343, an adjusting bottom surface 347 is formed at the bottom of the wedge stirring rod 343, the cross section of the rotation adjusting groove 344 is a sector, and the stirring adjusting plate 342 is abutted against a side wall of the rotation adjusting groove 344 far away from the stirring inclined plane 346.

Referring to fig. 3 and fig. 6 to fig. 7, a plurality of the inner and outer mixing assemblies 32 are fixedly mounted on two opposite side walls of the stirring main shaft 33, and a plurality of the inner and outer mixing assemblies 32 on the same side are equidistantly spaced along the vertical direction of the stirring main shaft 33, the inner and outer mixing assemblies 32 comprise a mixing support rod 321, a mixing tension spring 320, a mixing tension rod 322, a mixing sliding block 323, a mixing plate 324 and a balancing weight 325, the mixing support rod 321 is fixedly mounted on the side wall of the stirring main shaft 33, the mixing support rod 321 and the stirring support shaft 341 are mutually perpendicular, a mixing sliding groove 326 penetrating to the bottom is formed in the top of the mixing support rod 321, a mixing tension groove 327 is formed in one end of the mixing tension spring 320, which is close to the stirring main shaft 33, the mixing tension rod 322 is fixedly mounted on one end of the mixing tension rod 320, which is far away from the stirring main shaft 33, the mixing tension rod 322 is slidingly arranged in the mixing tension groove 327, the mixing sliding block 323 is fixedly mounted on one end of the mixing tension rod 322, which is far away from the stirring main shaft 33, and the mixing sliding block 326 is mutually perpendicular to the stirring support shaft 341, the mixing tension rod 326 is slidingly arranged on one side, which is far away from the mixing tension rod 324, and the top of the mixing tension rod is fixedly mounted on the top of the mixing tension rod 323.

Referring to fig. 2-3 and 5, the wall scraping mechanism 40 includes a wall scraping linkage assembly 50 and two wall scraping rotation assemblies 60, the wall scraping linkage assembly 50 includes a linkage rotating shaft 51, a linkage rotating block 52, a first linkage gear 53, a second linkage gear 54 and a linkage internal gear 55, the linkage rotating shaft 51 is rotatably mounted at the bottom of the stirring cavity 111, the top of the linkage rotating shaft 51 is fixedly connected with the bottom of the stirring main shaft 33, the linkage rotating block 52 is rotatably mounted at the bottom of the stirring cavity 111, the bottom of the stirring main shaft 33 passes through the top of the linkage rotating block 52, the stirring main shaft 33 is rotatably matched with the linkage rotating block 52, a gear accommodating groove 521 is formed at the bottom of the linkage rotating block 52, the linkage rotating shaft 51 is located in the gear accommodating groove 521, the first linkage gear 53 is fixedly mounted at the bottom of the linkage rotating shaft 51, the second linkage gear 54 is rotatably mounted at the bottom of the stirring cavity 111, the second linkage gear 54 is meshed with the first gear 53, the linkage internal gear 55 is fixedly mounted at the bottom of the stirring cavity 111, and the two linkage rotating blocks 55 are rotatably mounted at the two side walls 50 and rotatably arranged on the side walls of the two side walls of the linkage rotating assembly 52.

Referring to fig. 2-3 and 9-10, the wall scraping rotating assembly 60 includes a turning rod 61, a wedge arc rod 62, a plurality of turning connecting shafts 63 and a plurality of turning separating plates 64, the turning rod 61 is fixedly mounted on a side wall of the linkage rotating block 52, the bottom of the turning rod 61 is attached to the bottom of the stirring cavity 111, the turning rod 61 and the stirring spindle 33 are vertically arranged, the wedge arc rod 62 is fixedly mounted on one end of the turning rod 61 far away from the linkage rotating block 52, the wedge arc rod 62 and the turning rod 61 are vertically arranged, an attaching cambered surface 620 is formed on a side wall of the wedge arc rod 62 far away from the stirring spindle 33, the attaching cambered surface 620 is slidingly attached to a side wall of the stirring cavity 111, the plurality of turning connecting shafts 63 are mounted on a side wall of the wedge arc rod 62 facing the stirring spindle 33 at equal intervals along a vertical direction, the plurality of turning separating plates 64 are respectively fixedly mounted on one ends of the plurality of turning connecting shafts 63 facing the stirring spindle 33, a side wall 641 of the turning separating plates 64 is provided with a side wall of the turning separating plate 64, a side wall 641 facing the first magnetic separation block 643 and a side wall of the second magnetic separation block 643 is mounted on the side wall of the second magnetic separation block 643, and the side wall of the second magnetic separation block 643 is mounted on the side of the second magnetic separation plate is far away from the bottom of the first magnetic separation block 643.

Referring to fig. 2-3 and 9-10, a vertical linkage groove 621 is formed in the wedge-shaped arc rod 62, a vertical rotating shaft 622 is rotatably mounted at the top of the vertical linkage groove 621, the bottom of the vertical rotating shaft 622 is rotatably disposed at the bottom of the vertical linkage groove 621, one end of the turning connecting shaft 63 far away from the stirring main shaft 33 passes through the side wall of the wedge-shaped arc rod 62 and extends into the vertical linkage groove 621, a turning bevel gear 631 is fixedly mounted at one end of the turning connecting shaft 63 located in the vertical linkage groove 621, a plurality of driving bevel gears 623 are mounted at equal intervals along the axial direction of the vertical rotating shaft 622, the driving bevel gears 623 are respectively meshed with the turning bevel gears 631, a driven bevel gear 624 is fixedly mounted at the bottom of the vertical rotating shaft 622, the driving rotating shaft 611 is rotatably mounted on the turning rotating rod 61, one end of the driving rotating shaft 611 penetrates through the side wall of the wedge-shaped arc rod 62 to extend into the vertical linkage groove 621, the other end of the driving rotating shaft 611 penetrates through the side wall of the linkage rotating block 52 to extend into the gear accommodating groove 521, one end of the driving rotating shaft 611, which is located in the vertical linkage groove 621, is fixedly provided with the driving bevel gear 612, the driving bevel gear 612 is meshed with the driven bevel gear 624, one end of the driving rotating shaft 611, which is located in the gear accommodating groove 521, is fixedly provided with the triggering bevel gear 613, the bottom of the stirring cavity 111 is fixedly provided with the turning triggering piece 65, the turning triggering piece 65 is located in the gear accommodating groove 521, and the turning triggering piece 65 is used for intermittently rotating the triggering bevel gear 613.

Referring to fig. 8, the overturning trigger piece 65 includes two trigger supporting blocks 651 and a trigger ring 652, the two trigger supporting blocks 651 are fixedly mounted at the bottom of the stirring cavity 111, the two trigger supporting blocks 651 are respectively located at the front and rear sides of the first linkage gear 53, the trigger ring 652 is fixedly mounted at the top of the two trigger supporting blocks 651, an arc tooth slot 653 is formed at the top of the trigger ring 652, a plurality of trigger tooth blocks 654 are convexly arranged at the top of the arc tooth slot 653, and the top of the trigger ring 652 can be abutted against the bottom of the trigger bevel gear 613, so that the trigger bevel gear 613 cannot rotate, and the trigger bevel gear 613 can be driven to rotate by the plurality of trigger tooth blocks 654 when passing through the arc tooth slot 653.

Referring to fig. 1, a discharge chute is formed at the bottom of a side wall of the stirring shell 11, and is communicated with the stirring cavity 111, and a rotary door 13 is rotatably mounted on the discharge chute.

In an embodiment, when an operator pours different raw materials into the stirring cavity 111 from the two feed inlets 12 respectively, then the two feed inlets 12 are closed, the driving motor 22 is started, the driving motor 22 drives the driving wheel 23 to rotate through the driving belt 24, the driving wheel 23 can drive the stirring main shaft 33 to rotate, the stirring main shaft 33 can drive the plurality of stirring assemblies 31 and the internal and external mixing assemblies 32 to rotate, the stirring assemblies 31 can stir the raw materials in the stirring cavity 111 in the rotating process, so that the raw materials are mixed in the stirring cavity 111, the rotation of the plurality of internal and external mixing assemblies 32 can also play a stirring effect on the raw materials, the raw materials near the side wall of the stirring cavity 111 can be moved to the middle part of the stirring cavity 111, so that the raw materials near the outside in the stirring cavity 111 and the raw materials near the stirring main shaft 33 can be fully mixed, the mixing effect is improved, a plurality of stirring assemblies 31 can enable partial raw materials to float upwards for a certain distance in the process of rapid stirring, a stirring main shaft 33 can drive a scraping linkage assembly 50 and a scraping rotation assembly 60 to rotate, the raw materials attached to the side wall of a stirring cavity 111 can be scraped off by the rotation of the scraping rotation assembly 60, the raw materials are prevented from being attached to the side wall of the stirring cavity 111 all the time under the action of centrifugal force, so that full mixing cannot be obtained, the number of a plurality of inner and outer mixing assemblies 32 is equal to the number of a plurality of stirring pieces 34, the level of the inner and outer mixing assemblies 32 is higher than that of the corresponding stirring pieces 34, the level of a turnover separation plate 64 is equal to that of the corresponding inner and outer mixing assemblies 32, namely the level of the turnover separation plate 64 is higher than that of the corresponding stirring pieces 34, when the stirring piece 34 drives partial raw materials to float upwards in the stirring process, the floating partial raw materials can be screened and separated through the overturning separation plate 64, so that the mixing effect is further improved, the raw materials of the same type are prevented from being gathered and clustered to influence the mixing effect, the raw materials hung on the side wall of the stirring cavity 111 are scraped by the scraping wall rotating assembly 60 and are separated and fully mixed again through the overturning separation plate 64, the mixing efficiency is improved, the raw materials positioned near the side wall of the stirring cavity 111 are moved to the middle part through the rotation of the inner and outer mixing assembly 32, the raw materials in the stirring cavity 111, which are close to the outside, can be fully mixed with the raw materials, which are close to the stirring main shaft 33, so that the mixing effect is improved, the partial raw materials can float upwards through the rapid stirring of the stirring assembly 31, the raw materials can be scraped off through the rotation of the scraping wall rotating assembly 60, the raw materials attached to the side wall of the stirring cavity 111 are prevented from being insufficiently mixed, the raw materials can be separated through the separation, the mixing effect is further improved, the raw materials are prevented from being gathered and clustered, the rotation of the inner and outer mixing assembly 32 drives the driving wheel 23 and the stirring main shaft 33 through the rotation of the inner and outer mixing assembly 32, the stirring assembly 31 and the stirring main shaft 33 are fully mixed through the stirring assembly, and the stirring effect is improved, and the mixing effect is realized through the stirring effect is realized through the rotation of the scraping of the stirring assembly, the stirring assembly and the stirring assembly, the stirring assembly is realized.

In an embodiment, the distance between the stirring inclined plane 346 and the adjusting bottom surface 347 on the right side of the stirring main shaft 33 is gradually increased backwards, the distance between the stirring inclined plane 346 and the adjusting bottom surface 347 on the left side of the stirring main shaft 33 is gradually increased forwards, the stirring main shaft 33 rotates to drive the stirring supporting shaft 341 to rotate, the stirring supporting shaft 341 can drive the stirring adjusting plate 342 and the wedge stirring rod 343 to rotate, the rotation direction of the wedge stirring rod 343 is the direction towards the stirring inclined plane 346, when the stirring speed is slower, the wedge stirring rod 343 is in the initial state of holding for stirring due to the acting force of the torsion spring, the included angle between the stirring inclined plane 346 and the adjusting bottom surface 347 can play a role in separating raw materials in the rotating process, the separation effect of raw materials can be improved at the corner, the raw materials can be prevented from being coagulated into clusters, and part of raw materials can slightly float upwards through the stirring inclined plane 346, when the stirring speed is increased, the pressure of the stirring inclined plane 346 gradually increases, so that the wedge stirring rod 343 overturns against the acting force of the torsion spring, the stirring regulating plate 342 is propped against the side wall of the rotation regulating groove 344, which is close to the stirring inclined plane 346, after the wedge stirring rod 343 overturns for a certain angle, the inclination amplitude of the stirring inclined plane 346 is larger, part of raw materials can float along the stirring inclined plane 346 for a larger distance, the regulating bottom surface 347 also becomes inclined, a certain negative pressure is formed at the bottom of the regulating bottom surface 347 in the rotating process, part of raw materials below can float along the regulating bottom surface 347, the integral floating effect is greatly improved, the raw materials continuously sink by gravity and continuously float up through the wedge stirring rod 343, so that the raw materials can be continuously mixed up and down in the stirring cavity 111, thereby great improvement stirring effect, the present case is through stirring inclined plane 346 and adjust the contained angle between the bottom surface 347, and stirring inclined plane 346's slope range, can play the effect of separating the raw materials, the raw materials is at rotatory in-process, receive stirring inclined plane 346's pressure and slope, a portion raw materials can come up along stirring inclined plane 346, thereby with adjusting the raw materials separation on the bottom surface 347, separation effect has been improved, can further improve stirring inclined plane 346's inclination and come-up effect through wedge puddler 343's rotation, the raw materials can obtain abundant mixing and dispersion, be difficult to bond together and form the bulk, stirring inclined plane 346, adjust the cooperation of bottom surface 347 can make the raw materials mix constantly in stirring cavity 111 from top to bottom, the raw materials is through gravity subsidence and wedge puddler 343's upward floating motion, the circulation stirring of raw materials has been realized, can the intensive mixing raw materials, improve stirring effect, ensure the raw materials evenly mixing.

The stirring main shaft 33 can drive a plurality of mixing support rods 321 on the side wall to rotate in the rotating process, the mixing support rods 321 can mix raw materials in the rotating process, the horizontal height of the mixing support rods 321 is higher than that of the corresponding wedge stirring rods 343, the mixing support rods 321 can flap and mix raw materials floating up through the wedge stirring rods 343 in the rotating process, so that the mixing effect is improved, the mixing telescopic rods 322 can overcome the pulling force of the mixing tension springs 320 to move in the direction away from the stirring main shaft 33 through the centrifugal force during rotation of the mixing support rods 321, the mixing telescopic rods 322 can drive the mixing sliding blocks 323 to move in the direction away from the stirring main shaft 33, the mixing sliding blocks 323 can drive the mixing sheets 324 to move in the direction away from the stirring main shaft 33, and the top of each mixing sheet 324 is provided with a balancing weight 325, so the centrifugal force applied to the top of the mixing piece 324 is larger in the rotating process, so that the mixing piece 324 can turn over in the direction away from the stirring main shaft 33 against the acting force of the torsion spring, the maximum turning angle of the mixing piece 324 is close to ninety degrees, the turned mixing piece 324 can separate the original vertical direction in the rotating process, thereby better separating and mixing can be performed, after the mixing slide block 323 moves to the maximum distance, when the first magnetic block 328 approaches the second magnetic block 643, repulsive force can be generated between the first magnetic block 328 and the second magnetic block 643, so that the mixing slide block 323 and the mixing telescopic rod 322 slide in the direction of the stirring main shaft 33, and because the mixing piece 324 is still in the turning state at this time, when the mixing slide block 323 drives the turning state of the mixing piece 324 to slide in the direction of the stirring main shaft 33, the mixing piece 324 can push the raw materials that are close to on the lateral wall of the stirring cavity 111 to the middle part of the stirring cavity 111, when the first magnetic attraction block 328 is far away from the second magnetic attraction block 643, the mixing slide block 323, the mixing telescopic rod 322 and the mixing piece 324 are kept away from the stirring main shaft 33 again through centrifugal force so as to reciprocate, so that the raw materials on the lateral wall of the stirring cavity 111 can be mixed with the raw materials in the middle part of the stirring cavity 111, a sufficient mixing effect is achieved, the mixing telescopic rod 322 and the mixing slide block 323 can be driven to move in the direction away from the stirring main shaft 33 when the mixing support rod 321 rotates, meanwhile, the mixing piece 324 can be subjected to a turnover angle of ninety degrees to the maximum extent, separation and mixing in the vertical direction can be carried out, the mixing effect is further improved, and when the first magnetic attraction block 328 is close to the second magnetic attraction block 643, repulsive force can be generated, the mixing slide block 323, the mixing telescopic rod 322 and the mixing piece 324 can slide in the direction of the stirring main shaft 33, the raw materials are further pushed to the middle part of the stirring cavity 111, and the uniformity and the sufficiency of mixing are increased.

In another embodiment, the rotation of the stirring main shaft 33 can drive the linkage rotating shaft 51 to rotate, the linkage rotating shaft 51 can drive the first linkage gear 53 to rotate, the first linkage gear 53 can drive the second linkage gear 54 meshed with the first linkage gear 53 to rotate, the second linkage gear 54 can drive the linkage internal gear 55 meshed with the second linkage gear 54 to rotate, the linkage internal gear 55 can drive the linkage rotating block 52 to rotate, the rotation speed of the linkage rotating block 52 is smaller than that of the stirring main shaft 33, the rotation direction of the linkage rotating block 52 is opposite to that of the stirring main shaft 33, the linkage rotating block 52 can drive the turning rod 61 to rotate, the turning rod 61 can turn the raw materials at the bottom in the rotating process so as to mix the raw materials at the bottom, the raw materials are prevented from directly sinking in the bottom under certain conditions and cannot be fully mixed, the turning rod 61 can drive the wedge-shaped arc rod 62 to rotate, the attaching cambered surface 620 on the wedge-shaped arc rod 62 is attached to the side wall of the stirring cavity 111, so that the raw materials attached to the side wall of the stirring cavity 111 can be scraped off in the rotating process of the wedge-shaped arc rod 62, the raw materials are prevented from being attached to the side wall of the stirring cavity 111 all the time to influence the mixing effect, the wedge-shaped arc rod 62 can drive the turning connecting shaft 63 to rotate in the rotating process, the turning connecting shaft 63 can drive the turning separating plate 64 to rotate, the turning separating plate 64 can separate the raw materials through the sieving separating net 642, the raw materials can be prevented from being coagulated into clusters, the better mixing effect is achieved, the sieving separating net 642 can separate the raw materials floating up through the end part of the wedge-shaped stirring rod 343, the mutual matching can achieve the better mixing effect, in order to avoid the blocking of the sieving separation net 642 and to use a screen with a larger aperture, the separation effect of raw materials is mainly achieved, the raw materials at the bottom can be mixed through the cooperation of the linkage rotating shaft 51, the linkage inner gear 55, the linkage rotating block 52 and the two turning rotating rods 61, the raw materials at the bottom can be prevented from being directly sunk at the bottom and cannot be fully mixed under certain conditions, the raw materials attached to the side wall of the stirring cavity 111 are scraped off through the rotation of the turning rotating rods 61, the wedge-shaped arc rods 62 and the turning separation plate 64, the mixing effect is prevented from being influenced by the fact that the raw materials are always attached to the side wall, the raw materials are separated through the sieving separation net 642, the raw materials are prevented from being coagulated and the mixing effect is prevented from being influenced.

The turning rod 61 can drive the driving rotating shaft 611 to rotate around the axis of the linkage rotating block 52 in the rotating process, the turning rod 61 can drive the trigger bevel gear 613 to move around the axis of the linkage rotating block 52, when the trigger bevel gear 613 is propped against the top of the trigger circular ring 652, the trigger bevel gear 613 cannot rotate, when the trigger bevel gear 613 passes through the arc tooth grooves 653, the trigger bevel gear 613 can drive the driving rotating shaft 611 to rotate through the plurality of trigger tooth blocks 654, the driving rotating shaft 611 can drive the driving bevel gear 612 to rotate, the driving bevel gear 612 can drive the driven bevel gear 624 engaged with the driving bevel gear 612 to rotate, the driven bevel gear 624 can drive the vertical rotating shaft 622 to rotate, the vertical rotating shaft 622 can drive the plurality of driving bevel gears 623 to rotate, the bevel gear 623 is driven to rotate the bevel gear 631 engaged with the bevel gear, the bevel gear 631 can drive the connecting shaft 63 to rotate, the connecting shaft 63 can drive the separating plate 64 to rotate, the separating plate 64 can play a certain role in mixing during rotation, the separating plate 64 rotates for one hundred eighty degrees when the bevel gear 613 passes through the arc tooth slot 653 once, the screening surface can be replaced after the separating plate 64 rotates, thereby better avoiding the blocking of the screening separating net 642, the rotating separating plate 64 can enable the second magnetic block 643 to be positioned above, when the second magnetic block 643 is positioned above, the distance between the second magnetic block 643 and the first magnetic block 328 is far, a larger repulsive force can not be generated, the mixing slider 323 can overcome the centrifugal force to slide, only when the second magnetic block 643 is positioned below, the repulsive force generated by the second magnetic block 643 and the first magnetic block 328 can enable the mixing slider 323 to slide towards the direction of the stirring main shaft 33 against the centrifugal force, so that unstable situations caused by the fact that the mixing slider 323 slides back and forth with larger frequency can be avoided, the overturning separation plate 64 can overturn one hundred eighty degrees in the rotating process, a certain stirring effect can be achieved through overturning, the sieving surface can be replaced, the problem of blocking of the sieving separation net 642 can be effectively avoided, normal operation and separation effect of the device are guaranteed, the second magnetic block 643 is located above due to rotation of the overturning separation plate 64, the distance between the second magnetic block 643 and the first magnetic block 328 is far, the repulsive force between the second magnetic block 643 and the first magnetic block 328 is insufficient to overcome the centrifugal force, and therefore the sliding frequency and the unstable situations of the mixing slider 323 are reduced.

The installation process comprises the following steps: the two feed inlets 12 are respectively and fixedly arranged at the tops of the two feed tanks, the driving installation frame 21 is fixedly arranged on the top driving motor 22 of the stirring shell 11 and fixedly arranged on the side wall of one side of the driving installation frame 21, the driving wheel 23 is rotatably arranged at the top of the driving installation frame 21, the driving belt 24 is sleeved on the driving wheel 23 and the output shaft of the driving motor 22, the top of the stirring main shaft 33 is fixedly arranged in the driving wheel 23, the stirring supporting shaft 341 is fixedly arranged on the side wall of the stirring main shaft 33, the stirring adjusting plate 342 is fixedly arranged at the bottom of the stirring supporting shaft 341, the wedge-shaped stirring rod 343 is rotatably sleeved on the stirring supporting shaft 341 through the rotating shaft accommodating groove 345 through the torsion spring, the mixing supporting rod 321 is fixedly arranged on the side wall of the stirring main shaft 33, the mixing tension spring 320 is fixedly arranged at one end of the mixing tension spring 327 close to the stirring main shaft 33, the mixing telescopic rod 322 is fixedly arranged at one end of the mixing tension spring 320 far away from the stirring main shaft 33, the mixing sliding block 323 is fixedly arranged at one end of the mixing telescopic rod 322 far away from the stirring main shaft 33, the mixing sheet 324 is rotatably arranged at the top of the mixing sliding block 323 through a torsion spring, the balancing weight 325 is fixedly arranged at one side of the top of the mixing sheet 324 far away from the mixing sliding block 323, the linkage rotating shaft 51 is rotatably arranged at the bottom of the stirring cavity 111, the linkage rotating block 52 is rotatably arranged at the bottom of the stirring cavity 111, the stirring main shaft 33 is rotatably matched with the linkage rotating block 52, the second linkage gear 54 is rotatably arranged at the bottom of the stirring cavity 111, the linkage internal gear 55 is fixedly arranged at the bottom of the gear accommodating groove 521, the turning rod 61 is fixedly arranged on the side wall of the linkage rotating block 52, the wedge-shaped arc rod 62 is fixedly arranged at one end of the turning rod 61 far away from the linkage rotating block 52, the plurality of overturning connecting shafts 63 are arranged on the side wall of the wedge-shaped arc rod 62, which faces the stirring main shaft 33, at equal intervals along the vertical direction, the plurality of overturning separating plates 64 are respectively and fixedly arranged at one ends of the plurality of overturning connecting shafts 63, which face the stirring main shaft 33, the two triggering supporting blocks 651 are fixedly arranged at the bottom of the stirring cavity 111, and the triggering ring 652 is fixedly arranged at the top of the two triggering supporting blocks 651.

The scheme can be realized: 1. raw materials near the side wall of the stirring cavity 111 are moved to the middle part through rotation of the inner and outer mixing components 32, so that raw materials close to the outside and close to the stirring main shaft 33 in the stirring cavity 111 can be fully mixed, the mixing effect is improved, a plurality of stirring components 31 are rapidly stirred to enable partial raw materials to float upwards for a distance, the raw materials attached to the side wall of the stirring cavity 111 can be scraped off through rotation of the scraping rotating component 60, the raw materials are prevented from being fully mixed, the part of floating raw materials can be separated through screening separation by the overturning separating plate 64, the mixing effect is further improved, raw materials are prevented from gathering into clusters, the driving motor 22 drives the driving wheel 23 and the stirring main shaft 33 to rotate, the mixing is realized through rotation of the stirring component 31 and the inner and outer mixing components 32, and meanwhile the raw materials attached to the side wall of the stirring cavity 111 are fully mixed again through rotation of the scraping rotating component 60 and the overturning separating plate 64, and the mixing efficiency is improved.

2. Through the contained angle between stirring inclined plane 346 and the regulation bottom surface 347 to and the slope range of stirring inclined plane 346, can play the effect of separating the raw materials, the raw materials is at rotatory in-process, receive stirring inclined plane 346's pressure and slope, a part raw materials can come up along stirring inclined plane 346, thereby separate with the raw materials on the regulation bottom surface 347, separation effect has been improved, can further improve stirring inclined plane 346's inclination and come-up effect through wedge puddler 343's rotation, the raw materials can obtain abundant mixing and dispersion, be difficult to bond together and form the bulk, stirring inclined plane 346, the cooperation of regulation bottom surface 347 can make the raw materials mix about stirring cavity 111 constantly, the raw materials is through gravity subsidence and wedge puddler 343's upward floating motion, the circulation stirring of raw materials has been realized, can fully mix the raw materials, stirring effect is improved, ensure the raw materials evenly mix.

3. Can drive when rotatory and mix telescopic link 322 and mix slider 323 and remove to the direction of keeping away from stirring main shaft 33 through mixing the bracing piece 321, simultaneously mix piece 324 can carry out the biggest ninety degrees flip angle of being close to for can carry out separation and mixing on the vertical direction, further improve the effect of mixing, can produce repulsive force when first magnetism is inhaled piece 328 and is close to second magnetism and inhale piece 643, thereby make mix slider 323, mix telescopic link 322 and mix piece 324 and slide to the direction of stirring main shaft 33, further promote the raw materials to the middle part of stirring cavity 111, uniformity and the sufficiency of mixing have been increased.

4. Through the cooperation of linkage pivot 51, linkage internal gear 55, linkage rotary block 52 and two turndown bars 61 for the raw materials of bottom can mix, avoid directly submerging in the bottom and unable intensive mixing under certain circumstances, scrape down the raw materials that will adhere to on stirring cavity 111 lateral wall through the rotation of turndown bars 61, wedge arc pole 62 and upset separator plate 64, avoid it to adhere to on the lateral wall all the time and influence the mixing effect, separate the raw materials through sieving separator net 642, avoid the raw materials to condense into clusters, influence the mixing effect.

5. Through upset separation board 64 can carry out the upset of one hundred eighty degrees in rotatory in-process, the upset can play certain stirring effect, and can make the screening face obtain changing, can effectively avoid sieving the problem that separation net 642 blockked up, guarantee the normal operation and the separation effect of device, the rotation of upset separation board 64 makes second magnetic suction block position 643 in the top, distance between the first magnetic suction block 328 is farther, the repulsion force between second magnetic suction block 643 and the first magnetic suction block 328 is insufficient for overcoming centrifugal force, thereby the emergence of the slip frequency and the unstable condition of mixed slider 323 has been reduced.

All possible combinations of the technical features in the above embodiments are described, but should be considered as the scope of the description provided that there is no contradiction between the combinations of the technical features.

The above embodiments represent only a few embodiments of the present invention, which are described in more detail and are not to be construed as limiting the scope of the present invention. It should be noted that numerous variations and modifications could be made to the person skilled in the art without departing from the spirit of the invention, which would fall within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (10)

1. The utility model provides a vortex spins core spun yarn raw materials mixing arrangement, its characterized in that includes casing mechanism (10), actuating mechanism (20), rabbling mechanism (30) and scrapes wall mechanism (40), casing mechanism (10) are including stirring casing (11) and two feed inlets (12), stirring cavity (111) have been seted up to stirring casing (11) inside, two symmetrical feeding grooves that set up have been seted up at the top of stirring casing (11), and two the feeding groove all communicates with stirring cavity (111), two feed inlets (12) fixed mounting respectively in the top of two feeding grooves, actuating mechanism (20) fixed mounting is in the top of stirring casing (11), stirring mechanism (30) include stirring subassembly (31) and a plurality of inside and outside mixed subassembly (32), stirring subassembly (31) fixed mounting is in the bottom of actuating mechanism (20), and the bottom of stirring subassembly (31) runs through stirring casing (11) and extends to the bottom of stirring cavity (111), a plurality of inside and outside mixed subassembly (32) are installed in stirring subassembly (31) on stirring cavity (111), and a plurality of inside and outside mixed subassembly (32) are located stirring mechanism (40) in the bottom of stirring cavity (111);

The stirring assembly (31) comprises a stirring main shaft (33) and a plurality of stirring pieces (34), wherein the top of the stirring main shaft (33) is fixedly arranged in a driving wheel (23), the stirring pieces (34) are arranged on the side walls of two opposite sides of the stirring main shaft (33), the stirring pieces (34) on the same side are arranged at equal intervals along the vertical direction of the stirring main shaft (33), the inner and outer mixing assembly (32) comprises a mixing supporting rod (321), a mixing tension spring (320), a mixing telescopic rod (322), a mixing sliding block (323), a mixing sheet (324) and a balancing weight (325), the mixing supporting rod (321) is fixedly arranged on the side wall of the stirring main shaft (33), a mixing sliding groove (326) penetrating through the bottom is formed in the top of the mixing supporting rod (321), a mixing telescopic groove (327) is formed in one end of the mixing sliding groove (326) close to the stirring main shaft (33), the mixing telescopic rod (320) is fixedly arranged at one end of the mixing telescopic rod (322) close to the stirring main shaft (33), the mixing telescopic rod (322) is fixedly arranged at one end of the mixing telescopic rod (322) far away from the mixing telescopic groove (327) of the mixing main shaft (320), the mixing slide block (323) is fixedly arranged at one end, far away from the stirring main shaft (33), of the mixing telescopic rod (322), the mixing slide block (323) is arranged in the mixing slide groove (326) in a sliding mode, the mixing piece (324) is rotatably arranged at the top of the mixing slide block (323) through a torsion spring, and the balancing weight (325) is fixedly arranged at one side, far away from the mixing slide block (323), of the top of the mixing piece (324).

2. The vortex spinning core spun yarn raw material mixing device according to claim 1, wherein the driving mechanism (20) comprises a driving installation frame (21), a driving motor (22), a driving wheel (23) and a driving belt (24), the driving installation frame (21) is fixedly installed at the top of the stirring shell (11), the driving installation frame (21) is located between two feeding holes (12), the driving motor (22) is fixedly installed on one side wall of the driving installation frame (21), the driving wheel (23) is rotatably installed at the top of the driving installation frame (21), and the driving belt (24) is sleeved on the driving wheel (23) and an output shaft of the driving motor (22).

3. The vortex spinning core spun yarn raw material mixing device according to claim 2, wherein the stirring main shaft (33) is in running fit with the stirring shell (11), the stirring piece (34) comprises a stirring supporting shaft (341), a stirring adjusting plate (342) and a wedge stirring rod (343), the stirring supporting shaft (341) is fixedly arranged on the side wall of the stirring main shaft (33), the stirring supporting shaft (341) and the stirring main shaft (33) are mutually perpendicular, the stirring adjusting plate (342) is fixedly arranged at the bottom of the stirring supporting shaft (341), a rotating shaft accommodating groove (345) is formed in one end of the wedge stirring rod (343), the wedge stirring rod (343) is rotationally sleeved on the stirring supporting shaft (341) through a torsion spring, a rotation adjusting groove (344) is formed in the wedge stirring rod (343), the top of the rotation adjusting groove (344) is communicated with the rotating shaft accommodating groove (345), and the stirring adjusting plate (342) is located in the rotation adjusting groove (344).

4. A vortex spun core spun yarn raw material mixing apparatus as claimed in claim 3, wherein the cross section of the wedge stirring rod (343) is a right triangle, a stirring inclined surface (346) is formed on one side wall of the wedge stirring rod (343), the stirring inclined surface (346) on the right side of the stirring main shaft (33) is formed on the front side of the wedge stirring rod (343), a plurality of stirring inclined surfaces (346) on the left side of the stirring main shaft (33) are formed on the rear side of the wedge stirring rod (343), an adjusting bottom surface (347) is formed at the bottom of the wedge stirring rod (343), the cross section of the rotation adjusting groove (344) is a sector, and the stirring adjusting plate (342) is propped against one side wall of the rotation adjusting groove (344) far away from the stirring inclined surface (346).

5. The vortex spun core spun yarn raw material mixing device according to claim 4, wherein a plurality of the mixing support rods (321) on the same side are equidistantly arranged along the vertical direction of the stirring main shaft (33), and the mixing support rods (321) and the stirring support shaft (341) are mutually perpendicular.

6. The vortex spinning core-spun yarn raw material mixing device according to claim 5, wherein the wall scraping mechanism (40) comprises a wall scraping linkage assembly (50) and two wall scraping rotation assemblies (60), the wall scraping linkage assembly (50) comprises a linkage rotating shaft (51), a linkage rotating block (52), a first linkage gear (53), a second linkage gear (54) and a linkage internal gear (55), the linkage rotating shaft (51) is rotatably installed at the bottom of a stirring cavity (111), the top of the linkage rotating shaft (51) is fixedly connected with the bottom of a stirring main shaft (33), the linkage rotating block (52) is rotatably installed at the bottom of the stirring cavity (111), the bottom of the stirring main shaft (33) passes through the top of the linkage rotating block (52), the stirring main shaft (33) is in rotary fit with the linkage rotating block (52), a gear accommodating groove (521) is formed in the bottom of the linkage rotating block (52), the rotating shaft (51) is located in the gear accommodating groove (521), the first linkage gear (53) is fixedly installed at the bottom of the stirring cavity (54), the second linkage gear (54) is rotatably installed at the bottom of the linkage rotating block (52), the linkage internal gear (55) is fixedly arranged at the bottom of the gear accommodating groove (521), the linkage internal gear (55) is meshed with the second linkage gear (54), the two scraping wall rotating assemblies (60) are arranged on two outer side walls of the linkage rotating block (52), and the scraping wall linkage assemblies (50) are arranged on the side walls of the stirring cavity (111) in a sliding mode.

7. The vortex spinning core spun yarn raw material mixing device according to claim 6, wherein the wall scraping rotating assembly (60) comprises a turning rod (61), a wedge-shaped arc rod (62), a plurality of turning connecting shafts (63) and a plurality of turning separating plates (64), the turning rod (61) is fixedly arranged on the side wall of the linkage rotating block (52), the bottom of the turning rod (61) is attached to the bottom of the stirring cavity (111), the turning rod (61) is vertically arranged with the stirring main shaft (33), the wedge-shaped arc rod (62) is fixedly arranged at one end of the turning rod (61) far away from the linkage rotating block (52), the wedge-shaped arc rod (62) is vertically arranged with the turning rod (61), an attaching cambered surface (620) is formed on one side wall of the wedge-shaped arc rod (62) far away from the stirring main shaft (33), the plurality of the turning connecting shafts (63) are arranged at intervals along the vertical direction on the side wall of the linkage rotating block (111), the plurality of the wedge-shaped arc connecting shafts (63) are arranged towards one side wall of the stirring main shaft (33), the plurality of separating plates (64) are arranged at equal distances, the side wall of the stirring main shaft (33) is arranged towards one end of the stirring shaft (33), the separating plates (64) are respectively arranged at equal distances, the screen mesh installation groove (641) is internally and fixedly provided with a screening separation net (642), a first magnetic attraction block (328) is fixedly arranged at the bottom of one side wall of the mixing sliding block (323) far away from the stirring main shaft (33), a second magnetic attraction block (643) is fixedly arranged at the bottom of one side wall of the overturning separation plate (64) towards the stirring main shaft (33), and the polarities of the first magnetic attraction block (328) and the second magnetic attraction block (643) are the same.

8. The vortex spinning core spun yarn raw material mixing device according to claim 7, wherein a vertical linkage groove (621) is formed in the wedge-shaped arc rod (62), a vertical rotating shaft (622) is rotatably arranged at the top of the vertical linkage groove (621), the bottom of the vertical rotating shaft (622) is rotatably arranged at the bottom of the vertical linkage groove (621), one end of the turnover connecting shaft (63) far away from the stirring main shaft (33) penetrates through the side wall of the wedge-shaped arc rod (62) to extend into the vertical linkage groove (621), a turnover bevel gear (623) is fixedly arranged at one end of the turnover connecting shaft (63) positioned in the vertical linkage groove (621), a plurality of driving bevel gears (623) are arranged at equal intervals along the axial direction, the plurality of driving bevel gears (623) are respectively meshed with the plurality of turnover bevel gears (631), a driven bevel gear (624) is fixedly arranged at the bottom of the vertical rotating shaft (622), a driving rotating shaft (611) is rotatably arranged at one end of the turnover connecting shaft (63) far away from the stirring main shaft (33) and penetrates through the side wall of the wedge-shaped arc rod (62) to extend into the side wall (521) of the driving shaft (52) which extends, one end of the driving rotating shaft (611) located in the vertical linkage groove (621) is fixedly provided with a driving bevel gear (612), the driving bevel gear (612) is meshed with the driven bevel gear (624), one end of the driving rotating shaft (611) located in the gear accommodating groove (521) is fixedly provided with a trigger bevel gear (613), the bottom of the stirring cavity (111) is fixedly provided with a turnover trigger piece (65), the turnover trigger piece (65) is located in the gear accommodating groove (521), and the turnover trigger piece (65) is used for intermittently rotating the trigger bevel gear (613).

9. The vortex spinning core spun yarn raw material mixing device according to claim 8, wherein the overturning trigger piece (65) comprises two trigger supporting blocks (651) and a trigger ring (652), the two trigger supporting blocks (651) are fixedly installed at the bottom of the stirring cavity (111), the two trigger supporting blocks (651) are respectively located at the front side and the rear side of the first linkage gear (53), the trigger ring (652) is fixedly installed at the top of the two trigger supporting blocks (651), arc tooth grooves (653) are formed in the top of the trigger ring (652), a plurality of trigger tooth blocks (654) are convexly arranged at the top of the arc tooth grooves (653), the top of the trigger ring (652) can be abutted to the bottom of the trigger bevel gear (613) so that the trigger bevel gear (613) cannot rotate, and the trigger bevel gear (613) can be driven to rotate through a plurality of trigger tooth blocks (654) when passing through the arc tooth grooves (653).

10. The vortex spinning core spun yarn raw material mixing device according to claim 9, wherein a discharge chute is formed in the bottom of one side wall of the stirring shell (11), the discharge chute is communicated with the stirring cavity (111), and a rotary door (13) is rotatably arranged on the discharge chute.